Capacitor with multiple elements for multiple replacement applications

ABSTRACT

An apparatus includes a case having an elliptical cross-section capable of receiving a plurality of capacitive elements. One or more of the capacitive elements provide at least one capacitor having a first capacitor terminal and a second capacitor terminal. The apparatus also includes a cover assembly that includes a deformable cover mountable to the case, and, a common cover terminal having a contact extending from the cover. The cover assembly also includes at least three capacitor cover terminals, each of the at least three capacitor cover terminals having at least one contact extending from the deformable cover. The deformable cover is configured to displace at least one of the at least three capacitor cover terminals upon an operative failure of at least one of the plurality of the capacitive elements. The cover assembly also includes at least four insulation structures. One of the four insulation structures is associated with one of the at least three capacitor cover terminals. The apparatus also includes a first conductor capable of electrically connecting the first capacitor terminal of a capacitor provided by one of the plurality of capacitive elements to one of the at least three capacitor cover terminals and a second conductor capable of electrically connecting the second capacitor terminal of the capacitor provided by one of the plurality of capacitive elements to the common cover terminal.

CLAIM OF PRIORITY

This application is a continuation of U.S. application Ser. No. 15/974,073, filed May 8, 2018, which claims the benefit of priority under 35 U.S.C. § 119(e) to U.S. Provisional Application Ser. No. 62/505,517, filed on May 12, 2017, the entire contents of each of which are hereby incorporated by reference.

FIELD OF THE DISCLOSURE

The disclosure herein relates to a capacitor with multiple capacitor values selectively connectable to match the capacitance or capacitances of one or more capacitors being replaced.

BACKGROUND

One common use for capacitors is in connection with the motors of air-conditioning systems. The systems often employ two capacitors, one used in association with a compressor motor and another smaller value capacitor for use in association with a fan motor. Air-conditioning systems of different BTU capacity, made by different manufacturers or being a different model all may use capacitors having different values. These capacitors have a finite life and sometimes fail, causing the system to become inoperative.

A serviceman making a service call usually will not know in advance whether a replacement capacitor is necessary to repair an air-conditioning system, or what value capacitor or capacitors might be needed to make the repair. One option is for the serviceman to carry a large number of capacitors of different values in the service truck, but it is difficult and expensive to maintain such an inventory, especially because there can be a random need for several capacitors of the same value on the same day. The other option is for the serviceman to return to the shop or visit a supplier to pick up a replacement capacitor of the required value. This is inefficient as the travel time to pick up parts greatly extends the overall time necessary to complete a repair. This is extremely detrimental if there is a backlog of inoperative air-conditioning systems on a hot day. This problem presents itself in connection with air-conditioning systems, but is also found in any situation where capacitors are used in association with motors and are replaced on service calls. Other typical examples are refrigeration and heating systems, pumps, and manufacturing systems utilizing compressors.

A desirable replacement capacitor would have the electrical and physical characteristics of the failed capacitor, i.e. it should provide the same capacitance value or values at the same or higher voltage rating, be connectable using the same leads and be mountable on the same brackets or other mounting provision. It should also have the same safety protection, as confirmed by independent tests performed by Underwriter Laboratories or others. Efforts have been made to provide such a capacitor in the past, but they have not resulted in a commercially acceptable capacitor adapted for replacing capacitors having a wide range of capacitance values.

U.S. Pat. Nos. 3,921,041 and 4,028,595 disclose dual capacitor elements in the form of two concentric wound capacitor sections. My U.S. Pat. No. 4,263,638 also shows dual capacitors sections formed in a wound capacitive element, and my U.S. Pat. No. 4,352,145 shows a wound capacitor with dual elements, but suggests that multiple concentric capacitive elements may be provided, as does my U.S. Pat. Nos. 4,312,027 and 5,313,360. None of these patents show a capacitor having electrical and physical characteristics necessary to replace any one of the variety of failed capacitors that might be encountered on a service call.

An effort to provide a capacitor with multiple, selectable capacitance values is described in my U.S. Pat. No. 4,558,394. Three capacitance sections are provided in a wound capacitor element that is encapsulated in a plastic insulating material. An external terminal lug is connected with one of capacitor's sections and a second external terminal lug is provided with a common connection to all three capacitor sections. Pre-wired fixed jumper leads each connect the three capacitive sections in parallel, and the pre-wired fixed jumper leads have a portion exposed above the plastic encapsulation. This permits one or two jumper leads to be severed to remove one or two of the capacitor sections from the parallel configuration, and thereby to adjust the effective capacitance value across the terminal lugs. The '394 patent suggests that further combinations could be made with different connections, but does not provide any suitable means for doing so.

Another attempt to provide a capacitor wherein the capacitance may be selected on a service call is described in my U.S. Pat. No. 5,138,519. This capacitor has two capacitor sections connected in parallel, and has two external terminals for connecting the capacitor into a circuit. One of the terminals is rotatable, and one of the capacitor sections is connected to the rotatable terminal by a wire which may be broken by rotation of the terminal. This provides for selectively removing that capacitor section and thereby reducing the capacitance of the unit to the value of the remaining capacitor. This capacitor provides a choice of only two capacitance values in a fluid-filled case with a cover incorporating a pressure interrupter system.

In another effort to provide a universal adjustable capacitor for AC applications, American Radionic Co., Inc. produced a capacitor having five concentric capacitor sections in a cylindrical wound capacitor element. A common lead was provided from one end of the capacitor sections, and individual wire leads were provided from the other ends of the respective capacitor sections. The wound capacitor element was encapsulated in a plastic insulating material with the wire leads extending outwardly from the encapsulating material. Blade connectors were mounted at the ends of the wire leads, and sliding rubber boots were provided to expose the terminals for making connections and for shielding the terminals after connections were made. Various capacitance values could be selected by connecting various ones of the capacitor sections in parallel relationship, in series relationship, or in combinations of parallel and series relationships. In a later version, blade terminals were mounted on the encapsulating material. These capacitors did not meet the needs of servicemen. The connections were difficult to accomplish and the encapsulated structure did not provide pressure interrupter protection in case of capacitor failure, wherein the capacitors did not meet industry safety standards and did not achieve commercial acceptance or success.

Thus, although the desirability of providing a serviceman with a capacitor that is adapted to replace failed capacitors of a variety of values has been recognized for a considerable period of time, a capacitor that meets the serviceman's needs in this regard has not heretofore been achieved. This is a continuing need and a solution would be a considerable advance in the art.

SUMMARY OF THE INVENTION

An object of the disclosure is to provide a capacitor that is connectable with selectable capacitance values.

An object of the disclosure is to provide a capacitor incorporating multiple capacitance values that may be connected in the field to replace the capacitance value or values of a failed capacitor.

An object of the disclosure is to provide a capacitor having the objectives set forth above and which operates to disconnect itself from an electrical circuit upon a pressure-event failure.

An object of the disclosure is to incorporate multiple capacitance values in a single replacement capacitor that is adapted for connecting selected ones of the multiple capacitance values into a circuit.

An object of the disclosure to provide a capacitor having one or more of the foregoing objectives and which provides for safely making and maintaining connections thereto.

An object of the disclosure to increase the flexibility of replacing failed capacitors with capacitors incorporating multiple capacitance values by utilizing a range of tolerances in selecting the multiple capacitance values provided.

An object of the disclosure to provide a capacitor for replacing any one of a plurality of failed capacitors having different capacitance values and to meet or exceed the ratings and safety features of the failed capacitor.

In carrying out the disclosure herein, a replacement capacitor is provided having a plurality of selectable capacitance values. A capacitive element has a plurality of capacitor sections, each having a capacitance value. Each capacitor section has a section terminal and the capacitor sections are connected at a capacitive element common terminal. The capacitive element is received in a case together with an insulating fluid at least partially and preferably substantially surrounding the capacitive element. The case is provided with a pressure interrupter cover assembly, including a cover having a common cover terminal and a plurality of section cover terminals thereon. The section terminals of the capacitive element are respectively connected to the section cover terminals and the common terminal of the capacitive element is connected to the common cover terminal, with the pressure interrupter cover assembly adapted to break one or more connections as required to disconnect the capacitive element from an electrical circuit in the event that the capacitive element has a catastrophic pressure-event failure. The replacement capacitor is connected into an electrical circuit to replace a failed capacitor by connections to selected ones of the common cover terminal and section cover terminals, the capacitor sections and connections being selected to provide one or more capacitance values corresponding to the capacitor being replaced. Such connections may include connecting capacitor sections in parallel, connecting capacitor sections in series, connecting capacitor sections in combinations of parallel and series, and connecting one or more capacitor sections separately to provide two or more independent capacitance values.

In one aspect of the disclosure, the capacitive element is a wound cylindrical capacitive element having a plurality of concentric wound capacitor sections, each having a capacitance value. The number of capacitor sections is preferably six, but may be four or five, or may be greater than six. The capacitor section with the largest capacitance value is one of the outer three sections of the capacitive element. The capacitor sections are separated by insulation barriers and a metallic spray is applied to the ends of the capacitor sections. The insulation barriers withstand heat associated with connecting wire conductors to the capacitor sections.

In another aspect of the disclosure, the capacitive element is two or more wound cylindrical capacitive elements. There may be one wound cylindrical capacitive element for each capacitor section and capacitance value, and there may be four, five or six such wound cylindrical capacitive elements. Further, at least one of the two or more wound cylindrical capacitive elements may provide two or more capacitor sections. In a specific aspect, there are two wound cylindrical capacitive elements each providing three capacitor sections. The capacitor sections, however provided, are connected at a common terminal.

The case may employ one or more geometries, for example, the cross section of the case maybe cylindrical, having a cylindrical side wall, a bottom wall and an open top, to accommodate the one wound cylindrical capacitive element or to accommodate the plurality of wound capacitive elements providing the capacitor sections. The cross section of the case may also be elliptically shaped, for example, a case may be produced with an oval shaped cross-section.

Also, according to aspects of the disclosure, the pressure interrupter cover assembly includes a deformable circular cover having a peripheral edge sealingly secured to the upper end of the case. The common cover terminal and section cover terminals are mounted to the cover at spaced apart locations thereon, and have terminal posts extending downwardly from the cover to a distal end. A rigid disconnect plate is supported under the cover and defines openings therethrough accommodating the terminal posts and exposing the distal ends thereof. Conductors connect the capacitor section terminals and the common element terminal to the distal ends of the respective terminal posts of the section cover terminals and common cover terminal. The conductor connections at the distal ends of the terminal posts are broken upon outward deformation of the cover. In more specific aspects, the conductors connecting the capacitor sections to the distal ends of the section cover terminal posts are insulated wires, with the ends soldered to foil tabs that are welded or soldered to the distal ends of the terminal posts adjacent the disconnect plate.

Also, in some arrangements, the common cover terminal is positioned generally centrally on the cover, and the section cover terminals are positioned at spaced apart locations surrounding the common cover terminal. However, other layouts may be implemented for positioning the cover terminals and the common cover terminal. The section cover terminals include at least one blade connector, and preferably two or more blade connectors extending outwardly from the cover for receiving mating connectors for connecting selected ones of the capacitor sections into an electrical circuit. The common cover terminal preferably has four blade connectors.

Additional aspects of the disclosure include providing insulators for the section and common cover terminals, the insulators including cylindrical cups upstanding from the cover, with the cylindrical cup of at least the common cover terminal extending to or above the blades thereof. According to a preferred aspect of the invention, the insulators include a cover insulation barrier having a barrier cup upstanding from the cover and substantially surrounding a central common cover terminal and further having barrier fins radially extending from the barrier cup and deployed between adjacent section cover terminals.

The disclosure is carried out by connecting one or more capacitor sections into an electrical circuit, by attaching leads to the cover terminals. This includes connecting capacitor sections in parallel, connecting capacitor sections in series, connecting individual capacitor sections, or connecting capacitor sections in combinations of parallel and series, as required to match the capacitance value or values of the failed capacitor being replaced. The capacitor sections can be connected to replace multiple capacitor values, as required, to substitute the capacitor for the capacitor that has failed.

In another aspect of the disclosure, the capacitance values of the capacitor sections are varied within a tolerance range from a stated value, such that one capacitor section may be utilized effectively to replace one of two values, either individually or in combinations of capacitor sections.

In another aspect of the disclosure, an apparatus includes a case having an elliptical cross-section capable of receiving a plurality of capacitors, each having a capacitive value. Each capacitor having a first capacitor terminal and a second capacitor terminal. The apparatus also including a cover assembly with a peripheral edge sealingly secured to the case. The cover assembly includes a common cover terminal having a contact extending upwardly from the cover. The cover assembly also includes a plurality of capacitor cover terminals, each of the plurality of capacitor cover terminals having at least one contact extending upwardly from the cover. The cover assembly also includes a first conductor connecting the first capacitor terminal of one capacitor of the plurality of capacitors to one of the plurality of capacitor cover terminals and a second conductor connecting the second capacitor terminal of the capacitor to the common cover terminal. The cover assembly also includes an arrangement of insulator cups to form an insulation barrier between each pair of adjacent cover terminals. The common cover terminal and each of the plurality of capacitor cover terminals is individually positioned within one of the insulator cups.

In another aspect of the disclosure, an apparatus includes a case having an elliptical cross-section capable of receiving a plurality of capacitive elements. One or more of the capacitive elements provide at least one capacitor having a first capacitor terminal and a second capacitor terminal. The apparatus also includes a cover assembly that includes a deformable cover mountable to the case, and, a common cover terminal having a contact extending from the cover. The cover assembly also includes at least three capacitor cover terminals, each of the at least three capacitor cover terminals having at least one contact extending from the deformable cover. The deformable cover is configured to displace at least one of the at least three capacitor cover terminals upon an operative failure of at least one of the plurality of the capacitive elements. The cover assembly also includes at least four insulation structures. One of the four insulation structures is associated with one of the at least three capacitor cover terminals. The apparatus also includes a first conductor capable of electrically connecting the first capacitor terminal of a capacitor provided by one of the plurality of capacitive elements to one of the at least three capacitor cover terminals and a second conductor capable of electrically connecting the second capacitor terminal of the capacitor provided by one of the plurality of capacitive elements to the common cover terminal.

Implementations may include one or more of the following features. The plurality of capacitive elements may be each separately wound. The combined capacitance value of one of the plurality of capacitance elements may be greater than about 4.0 microfarads. Each of the at least four insulation structures may be cup shaped. Each of the insulation structures may be colored. At least two of the insulation structures may be differently colored. At least one capacitor may have a capacitance value in a range of about 1.5 microfarad to about 5.0 microfarad.

In another aspect of the disclosure, an apparatus includes a case having an elliptical cross-section capable of receiving a plurality of capacitive elements. One or more of the capacitive elements provide at least one capacitor having a first capacitor terminal and a second capacitor terminal. The apparatus also includes a cover assembly that includes a deformable cover mountable to the case, and, a common cover terminal having a contact extending from the cover. The cover assembly also includes at least three capacitor cover terminals, each of the at least three capacitor cover terminals having at least one contact extending from the deformable cover. The deformable cover is configured to displace at least one of the at least three capacitor cover terminals upon an operative failure. The cover assembly also includes at least four colored insulation structures. One of the four colored insulation structures is associated with one of the at least three capacitor cover terminals. The apparatus includes a first conductor capable of electrically connecting the first capacitor terminal of a capacitor provided by one of the plurality of capacitive elements to one of the at least three capacitor cover terminals and a second conductor capable of electrically connecting the second capacitor terminal of the capacitor provided by one of the plurality of capacitive elements to the common cover terminal.

Implementations may include one or more of the following features. The plurality of capacitive elements may be each separately wound. The combined capacitance value of one of the plurality of capacitance elements may be greater than about 4.0 microfarads. Each of the at least four colored insulation structures may be cup shaped. At least two of the colored insulation structures may be differently colored. The at least one capacitor has a capacitance value in a range of about 1.5 microfarads to about 5.0 microfarads.

In another aspect of the disclosure, an apparatus includes a case having an elliptical cross-section capable of receiving a plurality of capacitive elements. One or more of the capacitive elements provide at least one capacitor having a first capacitor terminal and a second capacitor terminal. The at least one capacitor has a capacitance value in a range of about 1.5 microfarads to about 5.0 microfarads. The apparatus also includes a cover assembly that includes a deformable cover mountable to the case, and, a common cover terminal having a contact extending from the cover. The cover assembly includes at least three capacitor cover terminals. Each of the at least three capacitor cover terminals has at least one contact extending from the deformable cover. The deformable cover is configured to displace at least one of the at least three capacitor cover terminals upon an operative failure. The cover assembly includes at least four insulation structures. One of the four insulation structures is associated with one of the at least three capacitor cover terminals. The apparatus also includes a first conductor capable of electrically connecting the first capacitor terminal of a capacitor provided by one of the plurality of capacitive elements to one of the at least three capacitor cover terminals and a second conductor capable of electrically connecting the second capacitor terminal of the capacitor provided by one of the plurality of capacitive elements to the common cover terminal.

Implementations may include one or more of the following features. The plurality of capacitive elements may be each separately wound. The combined capacitance value of one of the plurality of capacitance elements may be greater than about 4.0 microfarads. Each of the at least four insulation structures may be cup shaped. Each of the at least four insulation structures may be colored. At least two of the at least four insulation structures may be differently colored.

Other and more specific objects and features of the invention herein will, in part, be understood by those skilled in the art and will, in part, appear in the following description of the preferred embodiments, and claims, taken together with the drawings.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a perspective view of a capacitor according to the invention herein;

FIG. 2 is a top view of the capacitor of FIG. 1;

FIG. 3 is a sectional view of the capacitor of FIG. 1, taken along the lines 3-3 of FIG. 2;

FIG. 4 is a side elevation view of the capacitive element of the capacitor of FIG. 1, including wire conductors connected to the capacitor sections thereof;

FIG. 5 is a top view of the capacitive element of the capacitor of FIG. 1, including wire conductors connected to capacitor sections thereof;

FIG. 6 is an enlarged fragmentary plan view of a distal end of a wire conductor of FIGS. 4 and 5, connected to a foil tab;

FIG. 7 is an enlarged fragmentary side view of a distal end of a wire conductor of FIGS. 4 and 5, connected to a foil tab;

FIG. 8 is a sectional view of the capacitor of FIG. 1 taken along the lines 8-8 of FIG. 3, and showing a pressure interrupter cover assembly of the capacitor of FIG. 1;

FIG. 9 is an exploded perspective view of the pressure interrupter cover assembly of the capacitor of FIG. 1;

FIG. 10 is an enlarged fragmentary view of the pressure interrupter cover assembly of the capacitor of FIG. 1;

FIG. 11 is a top view of the capacitor of FIG. 1, shown with selected capacitor sections connected to a fan motor and a compressor motor;

FIG. 12 is a schematic circuit diagram of the capacitor of FIG. 1 connected as shown in FIG. 11;

FIG. 13 is a top view of the capacitor of FIG. 1 with jumper wires connecting selected capacitor sections in parallel, and also shown connected in an electrical circuit to a fan motor and a compressor motor;

FIG. 14 is a schematic circuit diagram of the capacitor of FIG. 1 connected as shown in FIG. 13;

FIG. 15 is a top view of the capacitor of FIG. 1 connecting selected capacitor sections in series, and also shown connected in an electrical circuit to a motor;

FIG. 16 is a schematic circuit diagram of the capacitor of FIG. 1 as connected shown in FIG. 15;

FIG. 17 is a top view of the capacitor of FIG. 1 with a jumper wire connecting selected capacitor sections in series, and also shown connected in an electrical circuit to a compressor motor;

FIG. 18 is a schematic circuit diagram of the capacitor of FIG. 1 connected as shown in FIG. 17;

FIG. 19 is a chart showing the single value capacitance values that may be provided by the capacitor of FIG. 1;

FIG. 20 is a chart showing dual value capacitances that may be provided by the capacitor of FIG. 1;

FIG. 21 is another chart showing dual value capacitances that may be provided by the capacitor of FIG. 1;

FIG. 22 is another chart showing dual value capacitances that may be provided by the capacitor of FIG. 1;

FIG. 23 is another chart showing dual value capacitances that may be provided by the capacitor of FIG. 1;

FIG. 24 is a sectional view of the capacitor of FIG. 1, taken generally along the lines 24-24 of FIG. 2, but showing the capacitor after failure of the capacitive element;

FIG. 25 is a sectional view of a capacitor according to the invention herein;

FIG. 26 is a side elevation view of the capacitive element of the capacitor of FIG. 25, including conductors connected to the capacitor sections thereof;

FIG. 27 is a folded top and bottom view of the capacitive element of the capacitor of FIG. 26 including conductors connected to capacitor sections thereof;

FIG. 28 is a sectional view of a capacitor according to the invention herein;

FIG. 29 is a perspective view of the capacitive element of the capacitor of FIG. 28, including some of the conductors connected to the capacitor sections thereof;

FIG. 30 is a top view of the capacitive element of the capacitor of FIG. 28, including conductors connected to capacitor sections thereof.

FIGS. 31A-C illustrate perspective views of a capacitor including an elliptically-shaped case;

FIGS. 32A-C illustrate front and side views of a capacitor including an elliptically-shaped case;

FIGS. 33A-C illustrate views of a cover assembly for an elliptically-shaped case; and

FIG. 34 is a schematic circuit diagram of the capacitor of FIG. 31(a)-(c).

FIG. 35 is a perspective view of an example of a capacitive element.

FIG. 36 is an electrical schematic of the capacitive element of FIG. 35.

FIG. 37 is a partial cross section view of the capacitive element of FIG. 35.

FIG. 38 is an example of a capacitor that includes a magnet.

FIG. 39 is an example of a capacitor that includes a magnet.

The same reference numerals refer to the same elements throughout the various Figures.

DETAILED DESCRIPTION

A capacitor 10 is shown in FIGS. 1-3, as well as in other Figures to be described below. The capacitor 10 is adapted to replace any one of a large number of capacitors. Therefore, a serviceman may carry a capacitor 10 on a service call and, upon encountering a failed capacitor, the serviceman can utilize the capacitor 10 to replace the failed capacitor with the capacitor 10 being connected to provide the same capacitance value or values of the failed capacitor.

The capacitor 10 has a capacitive element 12 having a plurality of capacitor sections, each having a capacitance value. The capacitive element 12 is also shown in FIGS. 4 and 5. In the preferred embodiment described herein, the capacitive element 12 has six capacitor sections 20-25. The capacitive element 12 is a wound cylindrical element manufactured by extension of the techniques described in my prior U.S. Pat. No. 3,921,041, my U.S. Pat. No. 4,028,595, my U.S. Pat. No. 4,352,145 and my U.S. Pat. No. 5,313,360, incorporated herein by reference. Those patents relate to capacitive elements having two capacitor sections rather than a larger plurality of capacitor sections, such as the six capacitor sections 20-25 of the capacitive element 12. Accordingly, the capacitive element 12 has a central spool or mandrel 28, which has a central opening 29. First and second dielectric films, each having a metalized layer on one side thereof, are wound in cylindrical form on the mandrel 28 with the non-metalized side of one film being in contact with the metalized side of the other. Selected portions of one or both of the metalized layers are removed in order to provide a multiple section capacitive element. Element insulation barriers are inserted into the winding to separate the capacitor sections, the element insulation barriers also assuming a cylindrical configuration. Five element insulation barriers 30-34 are provided to separate the six capacitor sections 20-25, with element insulation barrier 30 separating capacitor sections 20 and 21, element insulation barrier 31 separating capacitor sections 21 and 22, element insulation barrier 32 separating capacitor sections 22 and 23, element insulation barrier 33 separating capacitor sections 23 and 24, and element insulation barrier 34 separating capacitor sections 24 and 25.

The element insulation barriers are insulating polymer sheet material, which in the capacitive element 12 is polypropylene having a thickness of 0.005 inches, wound into the capacitive element 12. Thickness of 0.0025 to 0.007 may be used. Other materials may also be used. The barriers each have about 2¾-4 wraps of the polypropylene sheet material, wherein the element insulation barriers have a thickness of about 0.013 to 0.020 inches. The barriers 30-34 are thicker than used before in capacitors with fewer capacitor sections. The important characteristic of the barriers 30-34 is that they are able to withstand heat from adjacent soldering without losing integrity of electrical insulation, such that adjacent sections can become bridged.

As is known in the art, the metalized films each have one unmetalized marginal edge, such that the metalized marginal edge of one film is exposed at one end of the wound capacitive element 12 and the metalized marginal edge of the other film is exposed at the other end of the capacitive element 12. With reference to FIGS. 3 and 5, at the lower end of the capacitance element 12, the barriers 30-34 do not extend from the film, and an element common terminal 36 is established contacting the exposed metalized marginal edges of one metalized film of all the capacitor sections 20-25. The element common terminal 36 is preferably a zinc spray applied onto the end of the capacitive element 12.

At the top end of the capacitive element 12 as depicted in FIGS. 3 and 5, the element insulation barriers 30-34 extend above the wound metalized film. An individual capacitor element section terminal is provided for each of the capacitive sections 20-25, also by applying a zinc or other metallic spray onto the end of the capacitive element 12 with the zinc being deployed on each of the capacitor sections 20-25 between and adjacent the element insulation barriers 30-34. The element section terminals are identified by numerals 40-45. Element section terminal 40 of capacitor section 20 extends from the outer-most element insulation barrier 30 to the outer surface of the capacitive element 12, and the element section terminal 45 of capacitor section 25 extends from the inner-most element insulation barrier 34 to the central mandrel 28. Element section terminals 41-44 are respectively deployed on the capacitor sections 21-24.

Conductors preferably in the form of six insulated wires 50-55 each have one of their ends respectively soldered to the element section terminals 40-45, as best seen in FIG. 5. The thickness of the polypropylene barriers 30-34 resists any burn-through as a result of the soldering to connect wires 50-55 to the terminals 40-45.

The insulation of the wires 50-55 is color coded to facilitate identifying which wire is connected to which capacitor section. Wire 50 connected to element section terminal 40 of capacitor section 20 has blue insulation, wire 51 connected to element section terminal 41 of capacitor section 21 has yellow insulation, wire 52 connected to element section terminal 42 of capacitor section 22 has red insulation, wire 53 connected to element section terminal 43 of capacitor section 23 has white insulation, wire 54 connection to element section terminal 44 of capacitor section 24 has white insulation, and wire 55 connected to element section terminal 45 of capacitor section 25 has green insulation. These colors are indicated on FIG. 4.

The capacitive element 12 is further provided with foil strip conductor 38, having one end attached to the element common terminal 36 at 37. The foil strip conductor 38 is coated with insulation, except for the point of attachment 37 and the distal end 39 thereof. The conductor 50 connected to the outer capacitor element section 20 and its terminal 30 may also be a foil strip conductor. If desired, foil or wire conductors may be utilized for all connections.

In the capacitive element 12 used in the capacitor 10, the capacitor section 20 has a value of 25.0 microfarads and the capacitor section 21 has a capacitance of 20.0 microfarads. The capacitor section 22 has a capacitance of 10.0 microfarads. The capacitor section 23 has a capacitance of 5.5 microfarads, but is identified as having a capacitance of 5.0 microfarads for purposes further discussed below. The capacitor section 24 has a capacitance of 4.5 microfarads but is labeled as having a capacitance of 5 microfarads, again for purposes described below. The capacitor section 25 has a capacitance of 2.8 microfarads. The capacitor section 20 with the largest capacitance value also has the most metallic film, and is therefore advantageously located as the outer section or at least one of the three outer sections of the capacitive element 12.

The capacitor 10 also has a case 60, best seen in FIGS. 1-3, having a cylindrical side wall 62, a bottom wall 64, and an open top 66 of side wall 62. The case 60 is formed of aluminum and the cylindrical side wall 62 has an outside diameter of 2.50 inches. This is a very common diameter for capacitors of this type, wherein the capacitor 10 will be readily received in the mounting space and with the mounting hardware provided for the capacitor being replaced. Other diameters may, however, be used, and the case may also be plastic or of other suitable material.

The capacitive element 12 with the wires 50-55 and the foil strip 38 are received in the case 60 with the element common terminal 36 adjacent the bottom wall 64 of the case. An insulating bottom cup 70 is preferably provided for insulating the capacitive element 12 from the bottom wall 64, the bottom cup 70 having a center post 72 that is received in the center opening 29 of the mandrel 28, and an up-turned skirt 74 that embraces the lower side wall of the cylindrical capacitive element 12 and spaces it from the side wall 62 of the case 60.

An insulating fluid 76 is provided within the case 60, at least partly and preferably substantially surrounding the capacitive element 12. The fluid 76 may be the fluid described in my U.S. Pat. No. 6,014,308, incorporated herein by reference, or one of the other insulating fluids used in the trade, such as polybutene.

The capacitor 10 also has a pressure interrupter cover assembly 80 best seen in FIGS. 1-3, 8-10 and 24. The cover assembly 80 includes a deformable circular cover 82 having an upstanding cylindrical skirt 84 and a peripheral rim 86 as best seen in FIGS. 9 and 10. The skirt 84 fits into the open top 66 cylindrical side wall 62 of case 60, and the peripheral rim 86 is crimped to the open top 66 of the case 60 to seal the interior of the capacitor 10 and the fluid 76 contained therein, as shown in FIGS. 1 and 3.

The pressure interrupter cover assembly 80 includes seven cover terminals mounted on the deformable cover 82. A common cover terminal 88 is mounted generally centrally on the cover 82, and section cover terminals 90-95, each respectively corresponding to one of the capacitor sections 20-25, are mounted at spaced apart locations surrounding the common cover terminal 88. With particular reference to FIGS. 1, 2, 9 and 10, the section cover terminal 91 has three upstanding blades 98, 100 and 102 mounted on the upper end of a terminal post 104. Terminal post 104 has a distal end 105, opposite the blades 98, 100 and 102. The cover 82 has an opening 106 for accommodating the terminal post 104, and has a beveled lip 107 surrounding the opening. A shaped silicone insulator 108 fits snuggly under the cover in the beveled lip 107 and the terminal post 104 passes through the insulator 108. On the upper side of the cover, an insulator cup 110 also surrounds the post 104, and the insulator cup 110 sits atop the silicone insulator 108; thus, the terminal 91 and its terminal post 104 are well insulated from the cover 82. The other cover section terminals 92-95 are similarly mounted with an insulator cup and a silicone insulator.

The common cover terminal 88 has four blades 120, and a terminal post 122 that passes through a silicone insulator 112. The common cover terminal 88 mounts cover insulator barrier 114 that includes an elongated cylindrical center barrier cup 116 surrounding and extending above the blades 120 of the common cover terminal 88, and six barrier fins 118 that extend respectively radially outwardly from the elongated center barrier cup 116 such that they are deployed between adjacent section cover terminals 90-95. This provides additional protection against any arcing or bridging contact between adjacent section cover terminals or with the common cover terminal 88. Alternatively, the common cover terminal 88 may be provided with an insulator cup 116, preferably extending above blades 120 but with no separating barrier fins, although the barrier fins 118 are preferred. The terminal post 122 extends through an opening in the bottom of the base 117 of the insulating barrier cup 116, and through the silicone insulator 112, to a distal end 124.

The pressure interrupter cover assembly 80 has a fiberboard disc 126 through which the terminal posts 122, terminal post 104 and the terminal posts of the other section cover terminals extend. The disc 126 may be also fabricated of other suitable material, such as polymers. The terminal posts 104, 122, etc. are configured as rivets with rivet flanges 128 for assembly purposes. The terminal posts 104, 122, etc. are inserted through the disc 126, insulators 108, 112, insulator cups 110 and barrier cup 116, and the cover terminals 88, 90-95 are spot welded to the ends of the rivets opposite the rivet flanges 128. Thus, the rivet flanges 128 secure the cover terminals 88, 90-95 in the cover 82, together with the insulator barrier 114, insulator cups 110 and silicone insulators 108, 112. The fiberboard disc 126 facilitates this assembly, but may be omitted, if desired. The distal ends of the terminal posts are preferably exposed below the rivet flanges 128.

The cover assembly 80 has a disconnect plate 130, perhaps best seen in FIGS. 3, 9 and 10. The disconnect plate 130 is made of a rigid insulating material, such as a phenolic, is spaced below the cover 82 by a spacer 134 in the form of a skirt. The disconnect plate 130 is provided with openings accommodating the distal ends of the terminal posts, such as opening 136 accommodating the distal end 105 of terminal post 104 and opening 138 accommodating the distal end 124 of the terminal post 122. With particular reference to FIG. 9, the disconnect plate 130 may be provided with raised guides, such as linear guides 140 and dimple guides 142, generally adjacent the openings accommodating the distal ends of terminal posts. These guides are for positioning purposes as discussed below.

In prior capacitors having three or fewer capacitor sections, the conductors between the capacitor sections and the terminal posts were generally foil strips, such as the one used for the common element terminal 36 of the capacitive element 12 herein. The foil strips were positioned on a breaker plate over the distal ends of terminal posts, and were welded to the distal ends of the terminal posts. In capacitor 10, the distal end 39 of the foil strip 38 is connected to the distal end 124 of terminal post 122 by welding, as in prior capacitors.

The wires 50-55 are not well-configured for welding to the distal ends of the terminal posts of the cover section terminals. However, the wires 50-55 are desirable in place of foil strips because they are better accommodated in the case 60 and have good insulating properties, resist nicking and are readily available with colored insulations. In order to make the necessary connection of the wires 50-55 to their respective terminal posts, foil tabs 56 are welded to each of the distal ends of the terminal posts of the section cover terminals 90-95, and the guides 140, 142 are helpful in positioning the foil tabs 56 for the welding procedure. The attachment may be accomplished by welding the distal end of a foil strip to the terminal post, and then cutting the foil strip to leave the foil tab 56. Thereafter, and as best seen in FIGS. 6, 7 and 10, the conductor 58 of wire 50 is soldered to the tab 56, by solder 57. The insulation 59 of wire 50 has been stripped to expose the conductor 58. The other wires 51-55 are similarly connected to their respective cover section terminals. Alternatively, the foil tabs may be soldered to the wires and the tabs may then be welded to the terminal posts, if desired, or other conductive attachment may be employed.

Accordingly, each of the capacitor sections 20-25 is connected to a corresponding section cover terminal 90-95 by a respective one of color coded wires 50-55. The insulator cups 110 associated with each of the section cover terminals 90-95 are also color coded, using the same color scheme as used in the wires 50-55. This facilitates assembly, in that each capacitor section and its wire conductor are readily associated with the correct corresponding section cover terminal, so that the correct capacitor sections can be identified on the cover to make the desired connections for establishing a selected capacitance value.

The connections of the wires 50-55 and the foil 38 to the terminal posts are made prior to placing the capacitive element 12 in the case 60, adding the insulating fluid 76, and sealing the cover 82 of cover assembly 80 to the case 60. The case 60 may be labeled with the capacitance values of the capacitance sections 20-25 adjacent the cover terminals, such as on the side of case 60 near the cover 82 or on the cover 82.

The capacitor 10 may be used to replace a failed capacitor of any one of over two hundred different capacitance values, including both single and dual applications. Therefore, a serviceman is able to replace virtually any failed capacitor he may encounter as he makes service calls on equipment of various manufacturers, models, ages and the like.

As noted above, the capacitor 10 is expected to be used most widely in servicing air conditioning units. Air conditioning units typically have two capacitors; a capacitor for the compressor motor which may or may not be of relatively high capacitance value and a capacitor of relatively low capacitance value for a fan motor. The compressor motor capacitors typically have capacitances of from 20 to about 60 microfarads. The fan motor capacitors typically have capacitance values from about 2.5 to 12.5 microfarads, and sometimes as high as 15 microfarads, although values at the lower end of the range are most common.

With reference to FIG. 11, capacitor 10 is connected to replace a compressor motor capacitor and a fan motor capacitor, where the compressor motor capacitor has a value of 25.0 microfarads and the fan motor capacitor has a value of 4.0 microfarads. The 25.0 microfarad replacement capacitance for the compressor motor is made by one of the compressor motor leads 160 being connected to one of the blades of the blue section cover terminal 90 of capacitor section 20, which has a capacitance value of 25.0 microfarads, and the other compressor motor lead 161 being connected to one of the blades 120 of common cover terminal 88. The lead 162 from the fan motor is connected to the white section cover terminal 94 of capacitor section 24, and the second lead 163 from the fan motor is also connected to the common cover terminal 88. As set forth above, the actual capacitance value of the capacitor section 24 that is connected to the section cover terminal 94 is 4.5 microfarads, and the instructions and/or labeling for the capacitor 10 indicate that the capacitor section 24 as represented at terminal 94 should be used for a 4.0 microfarad replacement. Preferred labeling for this purpose can be “5.0 (4.0) microfarads” or similar. The 4.5 microfarad capacitance value is within approximately 10% of the specified 4.0 microfarad value, and that is within acceptable tolerances for proper operation of the fan motor. Of course, the capacitor section 24 and terminal 94 may be connected to replace a 5.0 microfarad capacitance value as well, whereby the 4.5 microfarad actual capacitance value of capacitor section 24 gives added flexibility in replacing failed capacitors. Similarly, the 5.5 microfarad capacitor section 23 can be used for either 5.0 microfarad or 6.0 microfarad replacement, and the 2.8 microfarad capacitor section 25 can be used for a 3.0 microfarad replacement or for a 2.5 microfarad additive value. FIG. 12 schematically illustrates the connection of capacitor sections 20 and 24 to the compressor motor and fan motor shown in FIG. 11.

FIG. 13 illustrates another connection of the capacitor 10 for replacing a 60.0 microfarad compressor motor capacitor and a 7.5 microfarad fan motor capacitor. The formula for the total capacitance value for capacitors connected in parallel is additive namely: C_(t)=C₁+C₂+C₃ . . . . Therefore, with reference to FIG. 13, a 60.0 microfarad capacitance value for the compressor motor is achieved by connecting in parallel the section cover terminal 90 (capacitor section 20 at a value of 25.0 microfarads), section cover terminal 91 (capacitor section 21 at a value of 20.0 microfarads), section cover terminal 92 (capacitor section 22 at a value of 10.0 microfarads) and section cover terminal 93 (capacitor section 23 at a nominal value of 5.0 microfarads). The foregoing connections are made by means of jumpers 164, 165 and 166, which may be supplied with the capacitor 10. Lead 167 is connected from the section cover terminal 90 of the capacitor section 20 to the compressor motor, and lead 168 is connected from the common cover terminal 88 to the compressor motor. This has the effect of connecting the specified capacitor sections 20, 21, 22 and 23 in parallel, giving a total of 60.0 microfarad capacitance; to wit: 25+20+10+5=60. It is preferred but not required to connect the lead from the compressor motor or the fan motor to the highest value capacitor section used in providing the total capacitance.

Similarly, a 7.5 microfarad capacitance is provided to the fan motor by connecting section cover terminal 94 of the 5.0 microfarad capacitor section 24 and the section cover terminal 95 of the nominal 2.5 microfarad capacitor section 25 in parallel via jumper 169. Leads 170 and 171 connect the fan motor to the common cover terminal 88 and the section cover terminal 95 of the capacitor section 25. FIG. 14 diagrammatically illustrates the connection of the capacitor 10 shown in FIG. 13.

It will be appreciated that various other jumper connections between section cover terminals can be utilized to connect selected capacitor sections in parallel, in order to provide a wide variety of capacitance replacement values.

The capacitor sections can also be connected in series to utilize capacitor 10 as a single value replacement capacitor. This has the added advantage of increasing the voltage rating of the capacitor 10 in a series application, i.e. the capacitor 10 can safely operate at higher voltages when its sections are connected in series. As a practical matter, the operating voltage will not be increased as it is established by the existing equipment and circuit, and the increased voltage rating derived from a series connection will increase the life of the capacitor 10 because it will be operating well below its maximum rating.

With reference to FIG. 15, the capacitor 10 is shown with capacitor section 22 (terminal 92) having a value of 10.0 microfarads connected in series with capacitor section 25 (terminal 95) having a nominal value of 2.5 microfarads to provide a replacement capacitance value of 2.0 microfarads. Leads 175 and 176 make the connections from the respective section cover terminals 92 and 95 to the motor, and the element common terminal 36 connects the capacitor sections 22 and 25 of capacitive element 12. With reference to FIG. 16, the connection of capacitor 10 shown in FIG. 15 is illustrated diagrammatically. In both FIGS. 15 and 16, it will be seen that the common cover terminal 88 is not used in making series connections.

The formula for capacitance of capacitors connected in series is

$\frac{1}{C_{T}} = {\frac{1}{C_{1}} + \frac{1}{C_{2}} + {\frac{1}{C_{3}}\mspace{14mu} \ldots}}$

Therefore,

${C_{T} = \frac{C_{1} \times C_{2}}{C_{1} + C_{2}}},$

and the total capacitance of the capacitor sections 22 and 25 connected as shown in FIGS. 15 and 16 is

$C_{T} = {\frac{10.0 \times 2.5}{10.0 + 2.5} = {\frac{25}{12.5} = 2.0}}$

microfarads. The capacitance of each of the capacitor sections 20-25 is rated at 440 volts. However, when two or more capacitor sections 20-25 are connected in series, the applied voltage section is divided between the capacitor sections in inverse proportion to their value. Thus, in the series connection of FIGS. 15 and 16, the nominal 2.5 microfarad section sees about 80% of the applied voltage and the 10.0 microfarad section sees about 20% of the applied voltage. The net effect is that the capacitor 10 provides the 2.0 microfarad replacement value at a higher rating, due to the series connection. In this configuration, the capacitor 10 is lightly stressed and is apt to have an extremely long life.

With reference to FIG. 17, the capacitor sections of the capacitor 10 are shown connected in a combination of parallel and series connections to provide additional capacitive values at high voltage ratings, in this case 5.0 microfarads. The two capacitor sections 23 and 24 each having a nominal value of 5.0 microfarads is connected in parallel by jumper 177 between their respective cover section terminals 93 and 94. The leads 178 and 179 from a compressor motor are connected to the section cover terminal 92 of capacitor section 22 having a value of 10.0 microfarads, and the other lead is connected to cover section terminal 94 of capacitor section 24. Thus, a capacitance value of 5.0 microfarads is provided according to the following formula

${\frac{1}{C_{T}} = {\frac{1}{C_{1}} + \frac{1}{C_{2}}}},$

where C₁ is a parallel connection having the value C+C, in this case 5.0+5.0 for a C₁ of 10.0 microfarads. With that substitution, the total value is

$C_{T} = {\frac{10.0 \times 10.0}{10 + 10} = {\frac{100}{20} = 5.0}}$

microfarads. The connection of capacitor 10 illustrated in FIG. 17 is shown diagrammatically in FIG. 18.

FIG. 19 is a chart showing single capacitance values that can be provided by the capacitor 10 connected in parallel. The values are derived by connecting individual capacitor sections into a circuit, or by parallel connections of capacitor sections. The chart should be interpreted remembering that the 2.8 microfarad capacitor section can be used as a 2.5 or 3.0 microfarad replacement, and that the two 5.0 microfarad values are actually 4.5 and 5.5 microfarad capacitor sections, also with possibilities for more replacements.

FIGS. 20-23 are charts showing applications of capacitor 10 in replacing both a fan motor capacitor and a compressor motor capacitor. This is an important capability, because many air conditioning systems are equipped with dual value capacitors and when one of the values fails, another dual value capacitor must be substituted into the mounting space bracket.

The chart of FIG. 20 shows dual value capacitances that can be provided by capacitor 10 wherein the nominal 2.5 microfarad capacitor section 25 is used for one of the dual values, usually the fan motor. Fan motors are generally not rigid in their requirements for an exact capacitance value, wherein the capacitor section 25 may also be used for fan motors specifying a 3.0 microfarad capacitor. The remaining capacitor sections 20-24 are available for connection individually or in parallel to the compressor motor, providing capacitance values from 5.0 to 65.0 microfarads in 5.0 microfarad increments.

The chart of FIG. 21 also shows dual value capacitances that can be provided by capacitor 10. In the chart of FIG. 21, one of the dual values is 5.0 microfarads that can be provided by either capacitor section 23 having an actual capacitance value of 5.5 microfarads or by capacitor section 24 having an actual capacitance of 4.5 microfarads. As discussed above, the capacitor section 24 can also be used for a 4.0 microfarad replacement value, and capacitor section 23 could be used for a 6.0 microfarad replacement value. Thus, the FIG. 21 chart represents more dual replacement values than are specifically listed. The other capacitor section may be used in various parallel connections to achieve the second of the dual capacitance values.

The chart of FIG. 22 illustrates yet additional dual value capacitances that can be provided by capacitor 10. Capacitor section 25 (nominal 2.5 microfarads) is connected in parallel with one of capacitor section 23 (5.5 microfarads) or capacitor section 24 (4.5 microfarads) to provide a 7.5 microfarad capacitance value as one of the dual value capacitances. The remaining capacitor sections are used individually or in parallel to provide the second of the dual value capacitances.

The FIG. 23 chart illustrates yet additional dual value capacitances that can be provided by capacitor 10, where capacitor section 22 (10 microfarads) is dedicated to provide one of the dual values. The remaining capacitor sections are used individually or in parallel for the other of the dual values.

It will be appreciated that any one or group of capacitor sections may be used for one of a dual value, with a selected one or group of the remaining capacitor sections connected to provide another capacitance value. Although there are no known applications, it will also be appreciated that the capacitor 10 could provide six individual capacitance values corresponding to the capacitor sections, or three, four or five capacitance values in selected individual and parallel connections. Additional single values can be derived from series connections.

The six capacitor sections 20-25 can provide hundreds of replacement values, including single and dual values. It will further be appreciated that if fewer replacement values are required, the capacitor 10 can be made with five or even four capacitor sections, and that if more replacement values were desired, the capacitor 10 could be made with more than six capacitor sections. It is believed that, at least in the intended field of use for replacement of air conditioner capacitors, there should be a minimum of five capacitor sections and preferably six capacitor sections to provide an adequate number of replacement values.

As is known in the art, there are occasional failures of capacitive elements made of wound metalized polymer film. If the capacitive element fails, it may do so in a sudden and violent manner, producing heat and outgassing such that high internal pressures are developed within the housing. Pressure responsive interrupter systems have been designed to break the connection between the capacitive element and the cover terminals in response to the high internal pressure, thereby removing the capacitive element from a circuit and stopping the high heat and overpressure condition within the housing before the housing ruptures. Such pressure interrupter systems have been provided for capacitors having two and three cover terminals, including the common terminal, but it has not been known to provide a capacitor with four or more capacitor sections and a pressure interrupter cover assembly.

The pressure interrupter cover assembly 80 provides such protection for the capacitor 10 and its capacitive element 12. With reference to FIG. 24, the capacitor 10 is shown after failure. Outgassing has caused the circular cover 82 to deform upwardly into a generally domed shape. When the cover 82 deforms in the manner shown, the terminal posts 104, 122 are also displaced upwardly from the disconnect plate 130, and the weld connection of the distal end 124 of common cover terminal post 122 to the distal end 39 foil lead 38 from the element common terminal 36 of the capacitive element 12 is broken, and the welds between the foil tabs 56 and the terminal posts 104 of the section cover terminals 90-95 are also broken, the separation at section cover terminals 91 and 94 being shown.

Although the preferred pressure interrupter cover assembly includes the foil lead 38 and foil tabs 56, frangibly connected to the distal ends of the terminal posts, the frangible connections both known in the art and to be developed may be used. As an example, the terminal posts themselves may be frangible.

It should be noted that although it is desirable that the connections of the capacitive element and all cover terminals break, it is not necessary that they all do so in order to disconnect the capacitive element 12 from a circuit. For all instances in which the capacitor 10 is used with its capacitor sections connected individually or in parallel, only the terminal post 122 of common cover terminal 88 must be disconnected in order to remove the capacitive element 12 from the circuit. Locating the common cover terminal 88 in the center of the cover 82, where the deformation of the cover 82 is the greatest, ensures that the common cover terminal connection is broken both first and with certainty in the event of a failure of the capacitive element 12.

If the capacitor sections of the capacitor 10 are utilized in a series connection, it is necessary that only one of the terminal posts used in the series connection be disconnected from its foil tab at the disconnect plate 130 to remove the capacitive element from an electrical circuit. In this regard, it should be noted that the outgassing condition will persist until the pressure interrupter cover assembly 80 deforms sufficiently to cause disconnection from the circuit, and it is believed that an incremental amount of outgassing may occur as required to cause sufficient deformation and breakage of the circuit connection at the terminal post of one of the section cover terminal. However, in the most common applications of the capacitor 10, the common cover terminal 88 will be used and the central location of the common cover terminal 88 will cause fast and certain disconnect upon any failure of the capacitive element.

Two other aspects of the design are pertinent to the performance of the pressure interrupter system. First, with respect to series connections only, the common cover terminal 88 may be twisted to pre-break the connection of the terminal post 122 with the foil strip 38, thus eliminating the requirement of any force to break that connection in the event of a failure of the capacitive element 12. The force that would otherwise be required to break the connection of common cover terminal post 122 is then applied to the terminal posts of the section cover terminals, whereby the section cover terminals are more readily disconnected. This makes the pressure interrupter cover assembly 80 highly responsive in a series connection configuration.

Second, the structural aspects of welding foil tabs to the distal ends of the terminal posts corresponding to the various capacitor sections and thereafter soldering the connecting wires onto the foil tabs 56 is also believed to make the pressure interrupter cover assembly 80 more responsive to failure of the capacitive element 12. In particular, the solder and wire greatly enhance the rigidity of the foil tabs 56 wherein upon deformation of the cover 82, the terminal posts break cleanly from the foil tabs 56 instead of pulling the foil tabs partially through the disconnect plate before separating. Thus, the capacitor 10, despite having a common cover terminal and section cover terminals for six capacitor sections, is able to satisfy safety requirements for fluid-filled metalized film capacitors, which is considered a substantial advance in the art.

Another capacitor 200 according to the invention herein is illustrated in FIGS. 26-28. The capacitor 200 has the same or similar external appearance and functionality as capacitor 10, and is adapted to replace any one of a large number of capacitors with the capacitor 200 connected to provide the same capacitance value or values of a failed capacitor.

The capacitor 200 is characterized by a capacitive element 212 having two wound cylindrical capacitive elements 214 and 216 stacked in axial alignment in case 60. The first wound cylindrical capacitive element 214 provides three capacitor sections 20 a, 22 a and 23 a, and the second wound cylindrical element 216 provides an additional three capacitive sections 21 a, 24 a and 25 a. These capacitor sections correspond in capacitance value to the capacitor sections 20-25 of capacitor 10, i.e. capacitor sections 20 and 20 a have the same capacitance value, capacitor sections 21 and 21 a have the same capacitance value, etc.

The wound cylindrical capacitive element 214 has a central spool or mandrel 228, which has a central opening 229. First and second dielectric films, each having metalized layer on one side thereof, are wound in cylindrical form on the mandrel 228 with the non-metalized size of one film being in contact with the metalized side of the other. Selected portions of one or both of the metalized layers are removed in order to provide multiple sections in the wound cylindrical capacitive element. Element insulation barriers 230 and 231 are inserted into the winding to separate the capacitor sections, the element insulation barriers also assuming a cylindrical configuration, with the element insulation barrier 230 separating capacitor sections 20 a and 22 a, and element insulation barrier 231 separating capacitor sections 22 a and 23 a. Zinc or other metal spray is applied between the barriers to form section terminals 40 a, 42 a and 43 a at one end of wound cylindrical capacitive element 214, and first common element terminal 36 a.

The second wound cylindrical capacitive element 216 is similarly formed, on a mandrel 226 with central opening 227, providing three capacitor sections 21 a, 24 a and 25 a, with insulation barriers 232 and 233 separating the sections. The insulation barriers may be as described above with respect to capacitive element 12, i.e. polypropylene barriers sufficient to withstand heat from adjacent soldering without loosing the integrity of electrical insulation. The capacitor sections 21 a, 24 a and 25 a are also metal sprayed to form section terminals 41 a, 44 a and 45 a with capacitance values respectively corresponding to sections 41, 44 and 45 of capacitive element 12.

Element common terminal 36 a′ is also formed. Element common terminal 36 a of wound cylindrical capacitive element 214 connects the sections 20 a, 22 a and 23 a thereof, and an element common terminal 36 a′ of wound cylindrical capacitive element 216 electrically connects the capacitor sections 21 a, 24 a and 25 a. The element common terminals 36 a and 36 a′ are connected by a foil strip 236, wherein they become the common terminal for all capacitor sections. The wound cylindrical capacitive elements 214 and 216 are stacked vertically in the case 60, with the common element terminals 36 a, 36 a′ adjacent to each other such that any contact between these common element terminals is normal and acceptable because they are connected as the common terminal for all capacitor sections. An insulator cup 270 is positioned in the bottom of case 60, to protect element section terminals 21 a, 24 a and 25 a from contact with the case 60 and a post 272 keeps the wound cylindrical elements 214 and 216 aligned and centered in case 60.

Conductors 50 a-55 a, preferably in the form of six insulated foil strips or insulated wires, each have one of their respective ends soldered to corresponding element section terminals 20 a-25 a, and have their other respective ends connected to the corresponding terminal posts of pressure interrupter cover assembly 80. One of the element common terminals 36 a, 36 a′ is connected to the common cover terminal post 122 by conductor 38 a. When the conductors are foil strips, all of the conductors may be connected as described above with respect to the foil strip 38, and if the conductors are insulated wire conductors they may be connected as described above with respect to the insulated wires 50-55. The case 60 is filled with an insulating fluid 76.

The length L of the two wound cylindrical capacitives 214 and 216, i.e. the length of the mandrels 226 and 228 on which the metalized dielectric sheet is wound, is selected in part to provide the desired capacitance values. The outer capacitor sections having the greater circumferencial dimension contain more metalized dielectric film than the capacitor sections more closely adjacent to the mandrels, and therefore provide a larger capacitance value. Thus, the longer wound cylindrical capacitive element 214 provides the 25 microfarad capacitor section 20 a and the 10 microfarad capacitor section 22 a, with the 5.5 microfarad capacitor section 23 a adjacent mandrel 238. The shorter wound cylindrical capacitive element 216 provides the 20 microfarad capacitor section 21 a, the 4.5 microfarad capacitor section 24 a and the 2.8 microfarad capacitor section 25 a.

A capacitive element 212 made up of two wound cylindrical capacitive elements 214 and 216 therefore provides the same capacitance values in its various capacitor sections as capacitive element 12 and, when connected to the cover section terminals 90-95, may be connected in the same way as described above with respect to the capacitor 10 and to provide the same replacement capacitance values shown in the charts of FIGS. 19-23.

With reference to FIGS. 28-30, another capacitor 300 is shown, also having the same or similar exterior appearance as the capacitor 10 and having the same functionality and replacing failed capacitors of varying values. The capacitor 300 includes case 60 and pressure interrupter cover assembly 80, and the capacitor 300 is characterized by a capacitive element provided in six separate wound cylindrical capacitive elements 320-325, each wound cylindrical capacitive element providing one capacitor section 20 b-25 b of the total capacitive element 312.

Accordingly, the capacitive element includes a first wound cylindrical capacitive element 320 which provides a capacitive section 20 b, preferably having a capacitance value of 25 microfarads. The capacitive section 20 b has a section terminal 40 b which is connected by conductor 50 b to section cover terminal 90 of the cover assembly 80, and has bottom common terminal 360. Wound cylindrical capacitor element 321 provides the capacitor section 21 b having a value of 20 microfarads, having a section terminal 41 b connected to the cover section terminal 91 by a conductor 51 b. This section also has a bottom terminal 361. Similarly, a wound cylindrical capacitive element 322 provides the capacitor section 22 b of capacitance value 10 microfarads, with section terminal 42 b connected to the corresponding section cover terminal 92 by conductor 52 c, and has a bottom terminal 362. Wound cylindrical capacitive element 325 provides capacitor section 25 b having sectional terminal 45 b connected to the section cover terminal 95 by insulated wire conductor 55 b. It also has a bottom terminal 325. The wound cylindrical capacitive element 325, providing only 2.8 microfarads of capacitance value, is quite small compared to the wound cylindrical capacitive elements 320, 321 and 322.

The four wound cylindrical capacitive elements 320, 321, 322 and 325 are oriented vertically within the case 60, but provide sufficient head room to accommodate two additional wound cylindrical capacitive elements 323 and 324, which are placed horizontally under the cover assembly 80. The wound capacitive element 323 provides capacitor section 23 b, preferably having a value of 4.5 microfarads, and the wound cylindrical capacitive element 324 provides capacitor section 24 b having a value of 5.5 microfarads. These capacitor sections have, respectively, section terminals 43 b and 44 b connected to cover terminals 93 and 94 by conductors 53 b and 54 b and bottom terminals 323 and 324.

All of the bottom terminals 320-325 are connected together to form common element terminal 36 b, and are connected to the common cover terminal 88. As best seen in FIG. 29, the bottom terminals 320, 321, 322 and 325 of the capacitor sections 20 b, 21 b, 22 b and 25 b are connected together by strips soldered or welded thereto, these strips providing both an electrical connection and a mechanical connection holding the assemblies together. Additionally, they may be wrapped with insulating tape. An insulated foil strip 38 b connects the aforesaid bottom terminals to the common cover terminal. The bottom terminals 323 and 324 of capacitor sections 23 b and 24 b are also connected together, and are further connected to the common cover terminal by an insulated foil strip 38 b′.

The wound cylindrical capacitive elements 320-325 are placed in case 60 with an insulating fluid 76. The capacitor 300 may be used in the same way as described above with respect to capacitor 10, to provide selected replacement values for a large number of different failed capacitors.

It will be noted that the wound cylindrical capacitive elements 320-325 occupy less space in the case 60 than the single wound cylindrical capacitive element 12 of capacitor 10. This is achieved by using thinner dielectric film wherein the capacitance values can be provided in less volume; however, the voltage rating of the wound cylindrical capacitive elements 320-325 is correspondingly less because of the thinner dielectric material. Thus, the capacitors made with this technique may have a shorter life, but benefit from a lower cost of manufacture.

Referring to FIGS. 31A-C, a capacitor 400 is presented that includes an elliptical-shaped case 402 (e.g., an oval-shaped case), which is partially shown in the exploded perspective view of FIG. 31A. The capacitor 400 provides a similar functionality as the capacitor 10, and is adapted to replace any of a large number of capacitors with the capacitor 400 being connected to provide a substantially similar (or equivalent) capacitance value or values of one or more failed capacitors. The capacitor 400 may include one or more of the design aspects, features, materials, etc. employed by the capacitors presented and described with respect to FIGS. 1-30. In this arrangement, the capacitor 400 includes two wound cylindrical capacitive elements 404 and 406 that are stacked on their respective sides such that the longitudinal axes of the elements are substantially parallel to each other. In some arrangements, the corresponding portions of each element's side may come into contact; although the sides of the elements may be separated by a distance in some arrangements (e.g., through the use a spacing device, a bracket, etc.). This positioning of the capacitive elements 404 and 406 may depend upon (or even defined in part by) the dimensions of the elliptically-shaped case 402. For example, due to the diameter, height, cylindrical shape, etc. of the capacitive elements, the geometry of the case 402 may constrain the layout of the components. However, in some arrangements one or more dimensions of a similarly elliptically-shaped case (e.g., an oval-shaped case) may adjusted (e.g., increased) to allow the capacitive elements to be positioned differently. For example, one or both of the capacitive elements may be rotated (with respect to their longitudinal axis by 90°) such that each element is vertically oriented (in comparison to the horizontal orientation illustrated in the figure). The manner in which the capacitive elements may be stacked amongst themselves may also be adjusted. For example, pairs of elements may be stacked end-to-end (a vertical stack) rather than side-by-side as shown in the figure.

In general, the capacitor 400 provides a functionality that is similar to the capacitor 10 and can be considered as being adaptable to replace any one of a large number of capacitors (with the capacitor 400) to provide the same capacitance value or values of a failed capacitor. Each of the capacitive elements 404 and 406 of the capacitor 400 can be implemented by using one or more production techniques, such as being wound elements like the two wound cylindrical capacitive elements 214 and 216. In this example, each of the capacitive elements 404 and 406 provide two capacitor sections, however in some arrangements either or both of the capacitive elements may provide more or less capacitive sections. Each capacitor section has a capacitance value that may be equivalent or different. In one arrangement, each of the capacitive elements may be used to provide the same pair of capacitance values. For example, capacitive element 404 may provide a 1.5 microfarads capacitance value and 5.0 microfarads capacitance, and, capacitive element 406 may similarly provide a 1.5 microfarads capacitance value and 5.0 microfarads capacitance. Other capacitance values may be provided either or both of the capacitive elements 404 and 406 (e.g., including values that are greater or less than values mentioned above), thereby providing a range of values. For example, the combined capacitance values provided by the capacitive elements may range from single digits (e.g., 1 microfarad) to two and three digits (e.g., tens or even hundreds of microfarads).

Similar to capacitive element 214, each of the capacitive elements 404 and 406 has a central spool or mandrel, which has a central opening. First and second dielectric films, each having a metalized layer on one side thereof, are wound in cylindrical form on the mandrel with the non-metalized side of one film being in contact with the metalized side of the other. Selected portions of one or both of the metalized layers are removed in order to provide multiple sections in the wound cylindrical capacitive element. Element insulation barriers (similar to barriers 230 and 231 shown in FIG. 25) may be inserted into the winding to separate the capacitor sections, the element insulation barriers also assuming a cylindrical configuration. Zinc or other metal spray may be applied between the barriers to form section terminals at one end of each of the wound cylindrical capacitive elements 404 and 406, along with a common element terminal for each capacitive element. The insulation barriers may be produced for a variety of materials such as polypropylene to withstand heat from soldering or other activities without losing the integrity of electrical insulation. Capacitor sections may also be metal sprayed to form section terminals.

In some arrangements capacitive elements may be adjusted to occupy more or less space. This may be achieved by using thinner dielectric film wherein the capacitance values can be provided in less volume; however, the voltage rating of the wound cylindrical capacitive elements may be correspondingly less due to the thinner dielectric material. Thus, the capacitors made with this technique may have a shorter life, but benefit from a lower cost of manufacture.

The common terminal of each capacitive element 404 and 406 respectively connects the sections of the corresponding element. In some arrangements, the element common terminals of the two capacitive elements 404 and 406 are connected using one or more conductors (e.g., foil strip(s), wire(s), etc.), wherein they become the common terminal for all capacitor sections. In some arrangements, an insulator cup 408 (e.g., similar to the insulator cup 270 shown in FIG. 25) is positioned in the bottom of the elliptically-shaped case 402, to protect the elements such as the lower positioned capacitive element 406 (and potentially other portions of the elements such as section terminals) from contact with the case. One or more mechanical mechanisms such as a bracket, a post, etc. may keep one or both of the wound cylindrical elements 404 and 406 in proper alignment.

Conductors, preferably in the form of insulated foil strips or insulated wires, each have one of their respective ends soldered to corresponding element section terminals and have their other respective ends connected to the corresponding terminal posts of a cover assembly such as a cover assembly 410. In some arrangements, the cover assembly 410 can assist in providing the functionality of a pressure interrupter, as described above. Typically a common terminal of each element is connected to a common cover terminal post by one or more conductors. The conductors may be foil strips, insulated wire conductors, etc., and one or more connection techniques may be employed. In some arrangements the case 402 may be filled with an insulating fluid (such as insulating fluid 76), however in some arrangements, an insulating fluid may not be used.

Geometry (length, shape, etc.), dimensions (e.g., length, diameter, etc.), etc. of either or both of the two wound cylindrical capacitive elements 404 and 406 may be selected in part to provide the desired capacitance values. The outer capacitor sections generally have greater circumferential dimension and contain more metalized dielectric film compared to the capacitor sections more closely adjacent to the mandrels, and therefore provide a larger capacitance value.

Each capacitive section has a section terminal which is connected by conductor to a corresponding one of the section cover terminals 412, 414 and 416 of the cover assembly 410, and has a bottom common terminal. Each of the bottom terminals of the capacitive elements 404, 406 are connected together to form a common element terminal, and is connected to the common cover terminal 418. The bottom terminals of the capacitor sections may be connected together by strips soldered, welded, etc., with these strips providing both an electrical connection and a mechanical connection holding the assemblies together. Additionally, they may be wrapped with insulating tape. An insulated foil strip may connect the bottom terminals to the common cover terminal 418.

As similarly illustrated in FIG. 10, each cover terminal (such as cover terminal 412) includes a number of upstanding blades (e.g., two blades) mounted on the upper end of a terminal post. The terminal post has a distal end, opposite the blades. The cover assembly 410 has an opening for accommodating the terminal post, and the opening may be formed of one or more shapes and include a variety of features such as a beveled lip that surrounds the opening.

Referring to FIGS. 32A-C, perspective views of the capacitor 400 are presented that show both the internal components of the capacitor (e.g., the capacitive elements 404 and 406) and portions of the elliptically-shaped case 402. In particular, FIG. 32A presents a front view of the capacitor 400 while FIG. 32B and FIG. 32C present left side and right side views of the capacitor 400. By representing the elliptically-shaped case as being somewhat transparent, the electrical connections between components are also presented. In this particular arrangement, a conductor 420 is used to connect a portion of capacitive element 404 and a portion of capacitive element 406 to connect capacitors in parallel to provide one capacitance value. A connector 422 then connects the parallel-connected capacitors to the cover terminal 412. Connectors 424 and 426 respectively connect individual capacitor sections of the capacitive elements 404 and 406 to the respective cover terminals 414 and 416. For a common connection, a connector 428 connects the respective common terminal of each capacitive element 404 and 406 to the common cover terminal 418. As mentioned above, one or more types of techniques may be employed for establishing the electrical connections, for example, one or more of the connectors may be electrical wires, metallic film, etc.

Referring to FIGS. 33A-C, three perspective views are provided for the cover assembly 410, which includes the three cover terminals 412, 414 and 416 along with the common cover terminal 418. With reference to FIGS. 3, 9 and 10, the cover assembly 410 may include a disconnect plate 430 that may be produced from a rigid insulating material, such as a phenolic. The disconnect plate 430 may include openings to accommodate the distal ends of the terminal posts for the cover terminals (e.g., the cover terminals 412, 414 and 416, the common cover terminal 418). The disconnect plate 430 may be provided with raised guides, such as linear guides and dimple guides, generally adjacent the openings accommodating the distal ends of terminal posts.

To provide protection to the capacitor 400, the cover assembly 410 may provide the functionality of a pressure interrupter. For example, if one or more of the capacitive elements 404, 406, or a portion of either or both elements were to fail; the elliptically-shaped cover of the cover assembly (or a portion of the cover) may deform upwardly due to outgassing of the failed element or elements. When deformed, the terminal posts are generally displaced upwardly from the disconnect plate 430, and the connection (e.g., a weld connection) between one or more terminals and the capacitive elements 404, 406 are broken.

In this particular arrangement, the cover terminals 412, 414 and 416 are positioned on the cover assembly 410 to form triangular-shaped group. The common cover terminal 418 is positioned at a location that can be considered slightly separated from the triangular-shaped group of the cover terminals 412, 414 and 416. Similar to the presented layout, other layouts, patterns, designs etc. may be employed to position the cover terminals and the common cover terminal upon the cover assembly. For example, the cover terminals 412, 414 and 416 may be positioned to generally surround the common cover terminal 418 in a manner similarly illustrated in FIG. 1 and FIG. 2, for example. In some arrangements one or more insulator techniques and mechanisms may be incorporated into the cover assembly 410. For example, and with reference to FIGS. 1 and 2, the cover assembly 410 may include an insulator barrier capable of separating two or more of the cover terminals and/or the common cover terminal. For example, the insulator barrier may include an elongated cylindrical center barrier cup capable of surrounding one or more of the terminals (e.g., the common cover terminal 418, cover terminal 412, etc.). In some arrangements the height of the barrier cup wall may extend above the height of the surrounded terminal or terminals. Insulation may also be provided by one or more fins that may extend between two or more terminals. For example, similar to the fins presented in FIGS. 1 and 2, fins may extend respectively radially outwardly from an elongated center barrier cup such that they are deployed between adjacent terminals (e.g., cover terminals). In some arrangements the height of the fins may extend above the height of the corresponding terminals, however, fins may also be employed that to not fully extend above the height of one or more of the terminals.

The elliptical shape of the cross section of the capacitor's case and the cover assembly may both approximately share a common ellipse shape. In general, the ellipse shape can be considered a curve on a plane surrounding two focal points such that a straight line drawn from one of the focal points to any point on the curve and then back to the other focal point has the same length for every point on the curve. An ellipse shape can also be considered as the set of points such that the ratio of the distance of each point on the curve from a given point (called a focus or focal point) to the distance from that same point on the curve to a given line (called the directrix) is a constant, referred to as the eccentricity of the ellipse. A circle can be considered as having an ellipse shape in which both focal points are positioned at the same location. The shape of an ellipse (e.g., how ‘elongated’ it is) is represented by its eccentricity which for an ellipse can be represented by any number from 0 (the limiting case of a circle) to arbitrarily close to but less than 1, for example. Ellipses can also be considered a closed type of conic section: a plane curve formed from the intersection of a cone by a plane.

Referring to FIG. 34, a schematic diagram of one potential arrangement for the circuitry of the capacitor 400 is presented. In this example, the capacitive elements are each produced to include two capacitor sections that correspondingly provide two capacitance values. In some arrangements, one or both of the capacitive elements may be used produced to provide more or less than two capacitive values. For example, on one potential arrangement, the capacitive element 404 may provide three capacitance values and capacitive element 406 may provide one capacitive value. Rather than providing a total of four capacitive values between the two capacitive elements 404, 406, more or less capacitive values may be provided. Further, while two capacitive elements 404, 406 are employed in this example, more or less capacitive elements may be used to provide capacitive values for a capacitor.

In this particular example, each of the capacitive elements 404, 406 provide equivalent capacitance values (e.g., 1.5 microfarad and 5.0 microfarad); however in some arrangements the elements may provide only one common value or entirely different capacitance values. The capacitance values provided by the capacitive elements 404 and 406 may also different in other arrangements. For example, values greater or less than 1.5 microfarads and/or 5.0 microfarads may be provided by the capacitive elements.

In this particular example, two of the cover terminals (i.e., cover terminals 414 and 416) are connected to the capacitive elements (by respective conductors 424 and 426) to each provide 5.0 microfarads (by electrically connecting to either cover terminal and the common cover terminal 418). The third cover terminal 412 is connected to both of the 1.5 microfarads capacitance values provided by the capacitive elements 404, 406. Connected in parallel, these two capacitance values combine to provide a capacitance value of 3.0 microfarads at the cover terminal 412. Along with connecting the two common sides of the capacitive elements, the conductor 428 also provides a connection to the common cover terminal 418 included in the cover assembly 410.

From the capacitance values (e.g., 1.5 microfarads and 5.0 microfarads) provided by the two capacitance elements 404 and 406, a variety of capacitance values are available from the capacitor 400. For example, by connecting the cover terminals 412, 414, 416 and the common cover terminal 418 in different variations, for example by using jumper wires, additional capacitance values may be provided. In the illustrated arrangement, along with the 5.0 microfarads capacitance provided by either of the cover terminals 414 and 416, a capacitance of 3.0 microfarad is provided by the cover terminal 412 (due the two 1.5 microfarad capacitance values connected in parallel). By connected either cover terminal 414 or 416 to the cover terminal 412 a capacitance value of 6.5 microfarad is provided (from the 1.5 microfarad capacitance value being connected in parallel with one of the 5.0 microfarad capacitance values). A capacitance value if 10.0 microfarad may be provided by connecting cover terminals 414 and 416 to place the two 5.0 microfarad capacitance values in parallel. By connecting all three of the cover terminals 412, 414, 416 a capacitance value of 13.0 microfarad is provided between the connected terminals (that connect each of the four capacitance values in parallel) and the common cover terminal 418. By adjusting the capacitance values provided by the capacitive elements 404 and 406, other levels of capacitance can be attained.

While the capacitor 400 illustrated in FIGS. 31-34 has largely been described as including two capacitive elements 404, 406, in some implementations, a capacitor may include a single capacitive element. Further, while the capacitor 400 has largely been described as including three section cover terminals 412, 414, 416, in some implementations, fewer section cover terminals may be included. For example, in implementations in which a capacitor includes a single capacitive element, two section cover terminals may be included (e.g., in addition to a common cover terminal). The capacitive element may include two capacitor sections, with each capacitor section providing a capacitive value (e.g., the same or different capacitive values).

Referring to FIGS. 35 and 36, an illustration of a wound capacitive element 3500 and a corresponding schematic diagram 3600 are presented. The capacitive element 3500 is an example of a capacitive device. A capacitive device can take on other forms besides a capacitive element. For example, a capacitive device may be a discrete capacitor, a section of a capacitor, or any other component that can provide a capacitance value. Therefore, while a capacitive element (e.g., a wound capacitive element) is an example of a capacitive device, other capacitive devices may be incorporated into the capacitors described herein.

As illustrated in the schematic diagram 3600, the capacitive element 3500 includes a pair of capacitors that share a common single plate 3520. To produce this capacitive element 3500, the two films can be wound on the spindle of a winding machine for a preselected number of revolutions. The number of revolutions generally depends upon the capacitance value desired. If the capacitance values of the dual capacitors are to be equal, one-half of the total length of the film is first wound. Once this portion is wound, the winding machine is stopped and voltage is applied to the metal layer of the film (e.g., by an electrode). The winding process is then continued, for example at a slower speed, and the metallic layer is vaporized, leaving a non-metallized intermediate region. The length of the non-metallized region is generally sufficient to encircle the capacitive element 3500 at least once. During the interval of winding the region around the capacitive element 3500, there is inserted into the section a non-conductive sheet 3536 of a material, such as a plastic. The sheet 3536 is generally not centered along the length of the cylindrical section of the element. As illustrated in FIG. 36, accordingly, upon continued winding the sheet 3536 forms a circular barrier which extends outwardly from that end of the capacitive element 3500 having the metallized edge of film. Winding is continued and terminated for the first and second films and the completed element may be wrapped, for example, by a suitable tape 3538.

As illustrated in FIG. 35, the capacitive element 3500 is metal plated in a manner employed for attaching leads, e.g. the ends are sprayed with molten copper to which a layer of solder is applied. Thereafter, the barrier formed by sheet 3536 is trimmed as shown in FIG. 37. The completed element, as shown in FIGS. 35 and 37 includes on one end, for example, a copper-solder layer 3550 which electrically engages the metallized layer 3520 of the first film (for the common single plate). The opposite end of the capacitive element 3500 includes a similar layer 3542 which, however, is interrupted by the barrier formed by sheet 3536 so that the inner layer engages that portion of metallized layer 3524 of the second film (for one capacitor plate) while the outer portion engages the metallized layer 3524 which succeeded the formation of the non-metallic region (for another capacitor plate). Thereafter, conductors 3544, 3546 may be soldered to these regions as indicated, and an opposite end of the conductors 3544, 3546 may be soldered to a corresponding section cover terminal, as described herein. A conductor 3548 may be similarly soldered to the opposite end, and an opposite end of the conductor 3548 may be soldered to a corresponding common cover terminal, as described herein. For example, because the capacitive element 3500 can provide two capacitor sections, two section cover terminals may be included. Generally, the capacitive element 3500 formed from metallized film is generally compact in size and simultaneously provides for the attachment of leads and maintaining the separate electrical integrity of the multiple capacitors included in the element. One or more of the techniques described herein may be employed for producing such capacitive elements.

Another capacitor 3800 according to the invention herein is illustrated in FIG. 38. In the illustrated example, the capacitor 3800 includes an elliptical-shaped case 3802 (e.g., an oval-shaped case). The capacitor 3800 may provide a similar functionality as the other capacitors described herein, and may be adapted to replace a number of capacitors with the capacitor 3800 being connected to provide a substantially similar (or equivalent) capacitance value or values of one or more failed capacitors. The capacitor 3800 may include one or more of the design aspects, features, materials, etc. employed by the capacitors presented and described with respect to FIGS. 1-37. In this arrangement, the capacitor 3800 includes a single wound cylindrical capacitive element 3804. In some arrangements, additional capacitive elements may be provided.

In general, the capacitor 3800 can provide a functionality that is similar to the other capacitors described herein. The capacitive element 3804 can be implemented by using one or more production techniques, such as being a wound element like the wound cylindrical capacitive elements 214 or 216. In the illustrated example, the capacitive element 3804 provides two capacitor sections, however, in some arrangements, the capacitive element 3804 may provide additional or fewer capacitive sections. Each capacitor section has a capacitance value that may be equivalent or different.

A common terminal of the capacitive element 3804 connects the sections of the capacitive element 3804. An insulator cup 3808 is positioned in the bottom of the case 3802 (e.g., to protect the elements such as the capacitive element 3804, and potentially other portions of the elements such as section terminals, from contact with the case 3802. One or more mechanical mechanisms such as a bracket, a post, etc. may keep the capacitive element 3804 in proper alignment.

Conductors, preferably in the form of insulated foil strips or insulated wires, each have one of their respective ends soldered to corresponding section terminals and have their other respective ends connected to the corresponding terminal posts of a cover assembly, such as a cover assembly 3810. In some arrangements, the cover assembly 3810 can assist in providing the functionality of a pressure interrupter, as described above. Typically, a common terminal of the capacitive element 3804 is connected to a common cover terminal post by one or more conductors. The conductors may be foil strips, insulated wire conductors, etc., and one or more connection techniques may be employed. In some arrangements, the case 3802 may be filled with an insulating fluid (such as insulating fluid 76), however in some arrangements, an insulating fluid may not be used.

Geometry (length, shape, etc.), dimensions (e.g., length, diameter, etc.), etc. of the capacitive element 3804 may be selected in part to provide the desired capacitance values. The outer capacitor section generally has greater circumferential dimension and contains more metalized dielectric film compared to the capacitor section more closely adjacent to the mandrels, and therefore provides a larger capacitance value.

Each capacitive section has a section terminal which is connected by conductor to a corresponding one of the section cover terminals 3812, 3814 of the cover assembly 3810, and has a bottom terminal. The bottom terminals are connected to the common cover terminal 3818. The bottom terminals may be connected together by strips soldered, welded, etc., with these strips providing both an electrical connection and a mechanical connection holding the assemblies together. Additionally, they may be wrapped with insulating tape. An insulated foil strip may connect the bottom terminals to the common cover terminal 3818.

In some implementations, the capacitive element 3804 includes a first capacitive section and a second capacitive section. The capacitive value provided by the first capacitive section may be 2.5 microfarads (or, e.g., approximately 2.5 microfarads) and the capacitive value provided by the second capacitive section may be 5.0 microfarads (or, e.g., approximately 5.0 microfarads). For example, the first capacitive section may include a section terminal that is connected by a conductor to one of the section cover terminals (e.g., the section cover terminal 3812), and the second capacitive section may include a section terminal that is connected by a conductor to the other section cover terminal (e.g., the section cover terminal 3814). Each of the capacitive sections may include a common terminal (e.g., sometimes referred to as bottom terminals) that are connected by a conductor to the common cover terminal 3818. In this way, a user can connect the section cover terminal 3812 and the common cover terminal 3818 to a device (e.g., an air conditioning system) to provide a capacitance value of 2.5 microfarads, and/or the user can connect the section cover terminal 3814 and the common cover terminal 3818 to a device to provide a capacitance value of 5.0 microfarads. The two capacitive sections can also be connected in parallel to provide a capacitance value of 7.5 microfarads. Such a capacitor may require two section cover terminals 3812, 3814 and one common cover terminal 3818. It should be understood that the first capacitive section and/or the second capacitive section may provide other capacitive values than those specifically described herein.

In some implementations, the capacitor 3800 may include one or more magnetic elements for assisting in mounting of the capacitor 3800 (e.g., to an air conditioning system). In the illustrated example, the capacitor 3800 includes a magnet 3820 positioned toward a bottom end of the capacitor 3800. In particular, the magnet 3820 is positioned near a bottom wall of the case 3802 of the capacitor 3800 on the insulator cup 3808. In some implementations, the magnet 3820 may be positioned between the bottom wall of the case 3802 of the capacitor 3800 and the insulator cup 3808. The magnet 3820 is configured to create magnetic attraction between the magnet 3820 and a magnetic surface in proximity to the capacitor 3800. For example, the magnet 3820 may cause the bottom wall of the case 3802 to be attracted to a metallic surface of an air conditioning system, thereby improving the integrity of a mounting between the capacitor 3800 and the air conditioning system after installation. The magnet 3820 may be designed such that the strength of magnetic attraction between the magnet 3820 and the air conditioning system is such that the magnet 3820 may remain firmly in place in response to possible vibration and/or other movement of the air conditioning system during operational use. In some implementations, the strength of magnetic attraction between the magnet 3820 and the air condition system is such that a user (e.g., a technician installing or uninstalling the capacitor 3800) can remove the capacitor from the surface of the air conditioning system without requiring excessive effort.

While the magnet 3820 is illustrated as being positioned interior to the case 3802 of the capacitor 3800, in some implementations, the magnet 3820 may be positioned outside of the case 3802 on an exterior of the bottom wall of the case 3802. For example, the magnet 3820 may have a disk shape that is positioned outside of the case 3802 at an outer surface of a base of the case 3802.

In some examples, the magnet 3820 may have a rectangular shape. For example, the magnet 3820 may be a rectangular strip that runs along the bottom wall of the case 3802 of the capacitor 3800. In particular, the rectangular strip may have a particular thickness, a first dimension that runs from the left side of the capacitor 3800 to the right side of the capacitor 3800, and a second dimension that is perpendicular to the first dimension and smaller than the first dimension. In some implementations, the magnet 3820 may have a square shape (e.g., such that the first dimension is equal to or substantially equal to the second dimension). In some implementations, the magnet 3820 may have a rod shape. In some implementations, the magnet 3820 may have a circular shape (e.g., a disk shape) or a hollow circular shape (e.g., a ring shape). For example, in some implementations, the magnet 3820 may have dimensions equal to or substantially equal to the dimensions of a disk-shaped battery (e.g., a watch battery such as a CR2032 battery). In some implementations, the magnet 3820 is a disk-shape with a thickness of approximately 4 mm and a diameter of approximately 160 mm. In some implementations, the magnet 3820 is a disk-shape with a thickness of approximately 4 mm and a diameter of approximately 40 mm. In some implementations, the magnet 3820 is a disk-shape with a thickness of approximately 4.5-5 mm and a diameter of about 60 mm. In some implementations, the magnet 3820 is a disk-shape with a thickness of approximately 5 mm and a diameter of about 60 mm

In some implementations, other shapes, a combination of shapes, etc. may be employed; for example, various types of curves may be incorporated into one or more magnetic strips (e.g., elongated oval shaped strips). Patterns of magnetic material may be used; for example, two crossed magnetic strips, a pattern of crosses, circles, etc. may be attached, incorporated into the bottom wall, side wall, etc. of the capacitor 3800.

The particular shape and/or dimensions of the magnet 3820 may be chosen to achieve the desired strength of magnetic attraction. For example, the magnet 3820 may be designed with a particular shape and/or larger dimensions and/or larger thicknesses to achieve a relatively higher strength of magnetic attraction with a magnetic surface. In some implementations, increased surface area of the magnet 3820 toward the bottom wall of the case 3802 of the capacitor 3800 may increase the strength of magnetic attraction.

In some implementations, the magnet 3820 has a strength of approximately 30-40 milliTeslas (mT) or a strength of approximately 65-75 mT. In some implementations, the strength of magnetic attraction can be increased by stacking multiple magnets 3820 (e.g., on top of each other). In some implementations, two stacked magnets 3820 can have a strength of approximately 70-80 mT, 60-80 mT, or 130-150 mT, although other ranges are also possible. In some implementations, the magnet 3820 may be a D40×4 ferrite ceramic magnet manufactured by Hangzhou Honesun Magnet Co., Ltd.

In some implementations, the magnet 3820 may be magnetized using one or more of a plurality of techniques. For example, in some implementations, the magnet 3820 may be magnetized such that a north and a south pole of the magnet 3820 is located at a particular position of the magnet 3820. For example, the techniques for magnetizing the magnet 3820 may cause the north and/or south pole to be located at various thicknesses of the magnet 3820, various axial positions of the magnet 3820, various diametric positions of the magnet 3820, and/or various radial positions of the magnet 3820. In some implementations, the magnet 3820 may be a multi-pole magnet.

In some implementations, the magnet 3820 is a permanent magnet that is made from a material that is magnetized and creates its own persistent magnetic field. For example, the magnet 3820 may be made from a ferromagnetic material that can be magnetized, such as iron, nickel, cobalt, and/or an alloy of rare-earth metals, among others. In some implementations, the magnet 3820 is a ferrite and/or ceramic magnet. In some implementations, the magnet 3820 may include one or more of ferric oxide, iron oxide, barium, barium carbonate, strontium, and/or strontium carbonate. The magnet 3820 may include one or more magnetically “hard” materials (e.g., materials that tend to stay magnetized). Alternatively or additionally, the magnet 3820 may include one or more magnetically “soft” materials.

In some implementations, the magnet 3820 may be a rare-earth magnet. A rare-earth magnet is typically a relatively strong permanent magnet that is made from one or more alloys of rare-earth elements. Example of rare-earth elements that can be used in a rare-earth magnet include elements in the lanthanide series, scandium, and yttrium, although other elements may also or alternatively be used. In some implementations, the rare-earth magnet may produce a magnetic field of greater than 1.0T (teslas). In some implementations, the rare-earth magnet may include one or both of samarium-cobalt and neodymium.

In some implementations, the magnet 3820 may be made from one or more ceramic compounds (e.g., ferrite) that can be produced by combining iron oxide and one or more metallic elements. In some implementations, such ceramic compounds may be electrically nonconductive. The use of such ceramic compounds for the magnet 3820 may eliminate the inclusion of electrically conductive elements in the capacitor 3800 that may otherwise affect the operation of the capacitor 3800.

In some implementations, the magnet 3820 may have a grade that corresponds to a particular standard (e.g., a National and/or International standard). In some implementations, the grade of the magnet 3820 corresponds to the Chinese ferrite magnet nomenclature system. For example, in some implementations, the magnet 3820 is grade Y10T, Y25, Y30, Y33, Y35, Y30BH, or Y33BH, although other grades are also possible. In some implementations, the grade corresponds to a working temperature of 250° C. In some implementations, the grade of the magnet 3820 corresponds to a Feroba, an American (e.g., “C”), or a European (e.g., “HF”) grading standard.

In some implementations, the magnet 3820 may be an electromagnet that produces a magnetic field by introducing an electric current. In some implementations, the electromagnet may include a magnetic core and a wire (e.g., an insulated wire) wound into a coil around the magnetic core. The magnetic core may be made from a ferromagnetic or a ferrimagnetic material such as iron or steel. The magnetic core may be made from a “soft” magnetic material (e.g., a magnetic material that can allow magnetic domains in the material to align upon introduction of the current through the coil).

By using an electromagnet as the magnet 3820, the strength of magnetic attraction can be turned on and off and/or customized according to the current passed through the coil. For example, current can be applied through the coil to cause the electromagnet to generate a magnetic field, and the current can be removed from the coil to cause the electromagnetic to cease generating the magnetic field. In some implementations, the strength of the magnetic field (and, e.g., the strength of magnetic attraction created by the electromagnet) can be adjusted based on the magnitude of electrical current passed through the coil. For example, relatively higher magnitudes of electrical current correspond to higher magnetic field strengths and therefore higher strengths of magnetic attraction (e.g., with a magnetic surface), and relatively lower magnitudes of electrical current correspond to lower magnetic field strengths and therefore lower strength of magnetic attraction.

In some implementations, the particular material used for the core of the electromagnet and/or the dimensions of the core may be chosen to achieve the desired strength of magnetic attraction. The core may be made from a material such as one or both of iron and steel. In some implementations, the dimensions of the coil and/or the number of turns of the coil may also be chosen to achieve the desired strength of magnetic attraction.

In some implementations, the current that is provided through the coil may be provided by a connection with one or both of the section cover terminals 3812, 3814 and the common cover terminal 3818 of the capacitor 3800. For example, a conductor (e.g., a wire) may be used to connect one or both of the section cover terminals 3812, 3814 to a first end of the coil and a conductor may be used to connect another one of the section cover terminals 3812, 3814 or the common cover terminal 3818 to a second end of the coil. In this way, the current that otherwise runs through the electrical components of the capacitor 3800 can also be used to power the electromagnetic, thereby causing the electromagnet to generate a magnetic field.

In some implementations, the capacitor 3800 may include one or more different and/or additional electrical components that can be used by the electromagnet to generate the magnetic field. For example, the capacitor 3800 may include a separate capacitor that is configured to store a charge to be used to subsequently apply current through the coil of the electromagnetic. In this way, the electromagnet may have a separate power source that can be used when generation of a magnetic field is desired.

In some implementations, the capacitor 3800 may include a switch that can be toggled by a user (e.g., a technician or an operator of the capacitor 3800) to cause the electromagnetic to generate or cease generating the magnetic field. The switch may cause an electrical connection in the coil to be temporarily broken and restored. In some implementations (e.g., implementations in which the coil is connected to one or both of the section cover terminals 3812, 3814 and/or the common cover terminal 3818), the switch may cause the conductor that connects the coil to one or both of the section cover terminals 3812, 3814 and/or the conductor that connects the coil to the common cover terminal 3818 to be temporarily broken and restored, such that the magnetic field generated by the electromagnet can be toggled on and off. In this way, the user can toggle the magnetic field on when mounting of the capacitor 3800 is desired (e.g., at the time of installation) and toggle the magnetic field off when mounting of the capacitor 3800 is not desired (e.g., when the capacitor 3800 is not in use and/or being stored) or when magnetic attraction is not desired (e.g., when mounting the capacitor 3800 at a location that does not include a magnetic surface).

In some implementations, the capacitive element 3804 (e.g., one or both of the sections of the capacitive element 3804) may be used to store the charge that is subsequently provided to the coil of the electromagnet to cause the magnetic field to be generated. In this way, electrical charge that is otherwise stored by the capacitor 3800 during typical use can also be used to power the electromagnet.

While the capacitor 3800 shown in the illustrated example includes one magnet 3820, additional magnets may also be provided. For example, a plurality of magnets may be positioned on the insulator cup 3808 or between the bottom wall of the case 3802 of the capacitor 3800 and the insulator cup 3808. The plurality of magnets may have dimensions that are relatively smaller than dimensions that may be chosen for implementations in which only a single magnet 3820 is used. The plurality of magnets may have dimensions substantially similar to dimensions of a watch battery, such as a CR2032 battery. The plurality of magnets may be positioned at various locations at the bottom wall of the case 3802. For example, the plurality of magnets may be arranged in a ring around a perimeter of the bottom wall such that the plurality of magnets are spaced approximately equidistant from one another. In some implementations, the plurality of magnets may be arranged in groups of two, three, etc. magnets. Any number of magnets may be provided to achieve the desired strength of magnetic attraction.

In some implementations, the capacitor 3800 includes two magnets 3820 positioned between the bottom wall of the case 3802 of the capacitor 3800 and the insulator cup 3808 of the capacitor 3800. In some implementations, the two magnets 3820 are each circular shape (e.g., disk shaped). The two magnets 3820 may have a stacked configuration such that a first disk shaped magnet is stacked on top of a second disk shaped magnet. In some implementations, the two magnets 3820 may have a combined strength of approximately 70-80 mT, 60-80 mT, or 130-150 mT, although other ranges are also possible. The two magnets 3820 may have the same or different diameters. In some implementations, the two magnets 3820 may be positioned at a location that is misaligned with a center of the bottom wall of the case 3802. For example, the center of the magnets 3820 may be misaligned with the center of the bottom wall of the case 3802 such that the magnets 3820 are positioned proximate to a side wall of the case 3802. In some implementations, the center of the magnets 3820 may be aligned with the center of the bottom wall of the case 3802. In some implementations, the centers of the two magnets 3820 may be misaligned relative to each other. In other words, a center of one of the magnets may be misaligned with a center of the other magnet.

Another capacitor 3900 according to the invention herein is illustrated in FIG. 39. In the illustrated example, the capacitor 3900 includes an elliptical-shaped case 3902 (e.g., an oval-shaped case). The capacitor 3900 may provide a similar functionality as the other capacitors described herein, and may be adapted to replace a number of capacitors with the capacitor 3900 being connected to provide a substantially similar (or equivalent) capacitance value or values of one or more failed capacitors. The capacitor 3900 may include one or more of the design aspects, features, materials, etc. employed by the capacitors presented and described with respect to FIGS. 1-38. In this arrangement, the capacitor 3900 includes a single wound cylindrical capacitive element 3904. In some arrangements, additional capacitive elements may be provided.

In general, the capacitor 3900 can provide a functionality that is similar to the other capacitors described herein. The capacitive element 3904 can be implemented by using one or more production techniques. In the illustrated example, the capacitive element 3904 provides two capacitor sections, however, in some arrangements, the capacitive element 3904 may provide additional or fewer capacitive sections. Each capacitor section has a capacitance value that may be equivalent or different.

A common terminal of the capacitive element 3904 connects the sections of the capacitive element 3904. An insulator cup 3908 is positioned in the bottom of the case 3902 (e.g., to protect the elements such as the capacitive element 3904, and potentially other portions of the elements such as section terminals, from contact with the case 3902. One or more mechanical mechanisms such as a bracket, a post, etc. may keep the capacitive element 3904 in proper alignment.

Conductors, preferably in the form of insulated foil strips or insulated wires, each have one of their respective ends soldered to corresponding section terminals and have their other respective ends connected to the corresponding terminal posts of a cover assembly, such as a cover assembly 3910. In some arrangements, the cover assembly 3910 can assist in providing the functionality of a pressure interrupter, as described above. Typically, a common terminal of the capacitive element 3904 is connected to a common cover terminal post by one or more conductors. The conductors may be foil strips, insulated wire conductors, etc., and one or more connection techniques may be employed. In some arrangements, the case 3902 may be filled with an insulating fluid, however in some arrangements, an insulating fluid may not be used.

Geometry (length, shape, etc.), dimensions (e.g., length, diameter, etc.), etc. of the capacitive element 3904 may be selected in part to provide the desired capacitance values. The outer capacitor section generally has greater circumferential dimension and contains more metalized dielectric film compared to the capacitor section more closely adjacent to the mandrels, and therefore provides a larger capacitance value.

Each capacitive section has a section terminal which is connected by conductor to a corresponding one of the section cover terminals 3912, 3914 of the cover assembly 3910, and has a bottom terminal. The bottom terminals are connected to the common cover terminal 3918. The bottom terminals may be connected together by strips soldered, welded, etc., with these strips providing both an electrical connection and a mechanical connection holding the assemblies together. Additionally, they may be wrapped with insulating tape. An insulated foil strip may connect the bottom terminals to the common cover terminal 3918.

In some implementations, the capacitive element 3904 includes a first capacitive section and a second capacitive section. The capacitive value provided by the first capacitive section may be 2.5 microfarads (or, e.g., approximately 2.5 microfarads) and the capacitive value provided by the second capacitive section may be 5.0 microfarads (or, e.g., approximately 5.0 microfarads). For example, the first capacitive section may include a section terminal that is connected by a conductor to one of the section cover terminals (e.g., the section cover terminal 3912), and the second capacitive section may include a section terminal that is connected by a conductor to the other section cover terminal (e.g., the section cover terminal 3914). Each of the capacitive sections may include a common terminal (e.g., sometimes referred to as bottom terminals) that are connected by a conductor to the common cover terminal 3918. In this way, a user can connect the section cover terminal 3912 and the common cover terminal 3918 to a device (e.g., an air conditioning system) to provide a capacitance value of 2.5 microfarads, and/or the user can connect the section cover terminal 3914 and the common cover terminal 3918 to a device to provide a capacitance value of 5.0 microfarads. The two capacitive sections can also be connected in parallel to provide a capacitance value of 7.5 microfarads. Such a capacitor may require two section cover terminals 3912, 3914 and one common cover terminal 3918. It should be understood that the first capacitive section and/or the second capacitive section may provide other capacitive values than those specifically described herein.

In some implementations, the capacitor 3900 may include one or more magnetic elements for assisting in mounting of the capacitor 3900 (e.g., to an air conditioning system). In the illustrated example, the capacitor 3900 includes a magnet 3920 positioned inside a side wall of the case 3902 of the capacitor 3900. The magnet 3920 is configured to create magnetic attraction between the magnet 3920 and a magnetic surface in proximity to the capacitor 3900. For example, the magnet 3920 may cause the side wall of the case 3902 to be attracted to a metallic surface of an air conditioning system, thereby improving the integrity of a mounting between the capacitor 3900 and the air conditioning system after installation. The magnet 3920 may be designed such that the strength of magnetic attraction between the magnet 3920 and the air conditioning system is such that the magnet 3920 may remain firmly in place in response to possible vibration and/or other movement of the air conditioning system during operational use. In some implementations, the strength of magnetic attraction between the magnet 3920 and the air condition system is such that a user (e.g., a technician installing or uninstalling the capacitor 3900) can remove the capacitor 3900 from the surface of the air conditioning system without requiring excessive effort.

In some examples, the magnet 3920 may have a rectangular shape. For example, the magnet 3920 may be a rectangular strip that runs from top to bottom along the side wall of the case 3902 of the capacitor 3900. In particular, the rectangular strip may have a particular thickness, a first dimension that runs from the top end of the capacitor 3900 to the bottom end of the capacitor 3900, and a second dimension that is perpendicular to the first dimension and smaller than the first dimension. In some implementations, the magnet 3920 may have a square shape (e.g., such that the first dimension is equal to or substantially equal to the second dimension). In some implementations, the magnet 3920 may have a rod shape. In some implementations, the magnet 3920 may have a circular shape (e.g., a disk shape) or a hollow circular shape (e.g., a ring shape). For example, in some implementations, the magnet 3920 may have dimensions equal to or substantially equal to the dimensions of a disk-shaped battery (e.g., a watch battery such as a CR2032 battery). In some implementations, other shapes, a combination of shapes, etc. may be employed; for example, various types of curves may be incorporated into one or more magnetic strips (e.g., elongated oval shaped strips). Patterns of magnetic material may be used; for example, two crossed magnetic strips, a pattern of crosses, circles, etc. may be attached, incorporated into the bottom wall, side wall, etc. of the capacitor 3900.

In some implementations, the magnet 3920 may have a curved shape that matches or substantially matches a curve of the case 3902 of the capacitor 3900. For example, the magnet 3920 may have a curve that allows the magnet 3920 to make continuous contact with the side wall of the case 3902 of the capacitor 3900.

In some implementations, the magnet 3920 may have dimensions of approximately 1 inch×1 inch and a thickness of about 1/10 of an inch. Such a magnet 3920 may be curved such that the magnet 3920 is configured to interface with an inner wall of the case 3902 of the capacitor 3900 (e.g., interior to the case 3900).

In some implementations, the magnet 3920 (e.g., the curved magnet) may be positioned exterior to the case 3902 of the capacitor 3900. In some implementations, a first surface of the magnet 3920 may be curved such that the first surface of the magnet 3920 interfaces with an exterior wall of the case 3902 of the capacitor 3900, and a second surface opposite of the first surface may have a substantially flat shape that is configured to interface with a flat surface of a separate object (e.g., a surface or wall of an air conditioning system). In some implementations, multiple curved magnets 3920 may be provided in one or more of the configurations described herein (e.g., including multiple curved magnets, a curved and a non-curved magnet, etc.).

In some implementations, the magnet 3920 may run along (e.g., make continuous contact) with the full perimeter of the side wall of the case 3902. That is, the magnet 3920 may have a sleeve shape with a diameter that is slightly less than a diameter of the capacitor 3900. In this way, substantially all of the side wall of the case 3902 of the capacitor 3900 may be magnetic such that the user can affix any portion of the side wall of the capacitor 3900 to a magnetic surface (e.g., without needing to rotate the capacitor 3900 to find a surface that is in line with the magnet 3920, as may be the case in implementations in which a magnet 3920 having a strip shape is used).

The particular shape and/or dimensions of the magnet 3920 may be chosen to achieve the desired strength of magnetic attraction. For example, the magnet 3920 may be designed with a particular shape and/or larger dimensions and/or larger thicknesses to achieve a relatively higher strength of magnetic attraction with a magnetic surface. In some implementations, increased surface area of the magnet 3920 toward the side wall of the case 3902 of the capacitor 3900 may increase the strength of magnetic attraction.

In some implementations, the magnet 3920 has a strength of approximately 30-40 milliTeslas (mT) or a strength of approximately 65-75 mT. In some implementations, the strength of magnetic attraction can be increased by stacking multiple magnets 3920 (e.g., one beside the other). In some implementations, two stacked magnets 3920 can have a strength of approximately 70-80 mT, 60-80 mT, or 130-150 mT, although other ranges are also possible. In some implementations, the magnet 3920 may be a D40×4 ferrite ceramic magnet manufactured by Hangzhou Honesun Magnet Co., Ltd.

In some implementations, the magnet 3920 may be magnetized using one or more of a plurality of techniques. For example, in some implementations, the magnet 3920 may be magnetized such that a north and a south pole of the magnet 3920 is located at a particular position of the magnet 3920. For example, the techniques for magnetizing the magnet 3920 may cause the north and/or south pole to be located at various thicknesses of the magnet 3920, etc. In some implementations, the magnet 3920 may be a multi-pole magnet

In some implementations, the magnet 3920 is a permanent magnet that is made from a material that is magnetized and creates its own persistent magnetic field. For example, the magnet 3920 may be made from a ferromagnetic material that can be magnetized, such as iron, nickel, cobalt, and/or an alloy of rare-earth metals, among others. In some implementations, the magnet 3920 is a ferrite and/or ceramic magnet. In some implementations, the magnet 3920 may include one or more of ferric oxide, iron oxide, barium, barium carbonate, strontium, and/or strontium carbonate. The magnet 3920 may include one or more magnetically “hard” materials (e.g., materials that tend to stay magnetized). Alternatively or additionally, the magnet 3920 may include one or more magnetically “soft” materials.

In some implementations, the magnet 3920 may be a rare-earth magnet. A rare-earth magnet is typically a relatively strong permanent magnet that is made from one or more alloys of rare-earth elements. Example of rare-earth elements that can be used in a rare-earth magnet include elements in the lanthanide series, scandium, and yttrium, although other elements may also or alternatively be used. In some implementations, the rare-earth magnet may produce a magnetic field of greater than 1.0T. In some implementations, the rare-earth magnet may include one or both of samarium-cobalt and neodymium.

In some implementations, the magnet 3920 may be made from one or more ceramic compounds (e.g., ferrite) that can be produced by combining iron oxide and one or more metallic elements. In some implementations, such ceramic compounds may be electrically nonconductive. The use of such ceramic compounds for the magnet 3920 may eliminate the inclusion of electrically conductive elements in the capacitor 3900 that may otherwise affect the operation of the capacitor 3900.

In some implementations, the magnet 3920 may have a grade that corresponds to a particular standard (e.g., a National and/or International standard). In some implementations, the grade of the magnet 3920 corresponds to the Chinese ferrite magnet nomenclature system. For example, in some implementations, the magnet 3920 is grade Y10T, Y25, Y30, Y33, Y35, Y30BH, or Y33BH, although other grades are also possible. In some implementations, the grade corresponds to a working temperature of 250° C. In some implementations, the grade of the magnet 3920 corresponds to a Feroba, an American (e.g., “C”), or a European (e.g., “HF”) grading standard.

Like the magnet 3820 described above with respect to FIG. 38, the magnet 3920 illustrated in FIG. 39 can also be an electromagnet that includes a core and a coil wrapped around the core, in which the materials, dimensions, configuration, and/or operating characteristics of the electromagnet can be chosen to achieve the desired strength of magnetic attraction.

While the capacitor 3900 shown in the illustrated example includes one magnet 3920, additional magnets may also be provided. For example, a plurality of magnets may be positioned proximate to the side wall of the case 3902 of the capacitor 3900. The plurality of magnets may have dimensions that are relatively smaller than dimensions that may be chosen for implementations in which only a single magnet 3920 is used. The plurality of magnets may have dimensions substantially similar to dimensions of a watch battery, such as a CR2032 battery. The plurality of magnets may be positioned at various locations proximate to the side wall of the case 3902. For example, the plurality of magnets may be arranged in a ring around a perimeter of the side wall such that the plurality of magnets are spaced approximately equidistant from one another. In some implementations, the plurality of magnets may be arranged in groups of two, three, etc. magnets. Any number of magnets may be provided to achieve the desired strength of magnetic attraction.

In some implementations, the capacitors 3800, 3900 may be configured to accept the magnet 3820, 3920 after manufacture of the capacitor 3800, 3900. For example, the capacitor 3800, 3900 may include one or more movable surfaces (e.g., doors or compartments) that can be opened by the user such that the user can place the magnet 3820, 3920 inside the capacitor 3800, 3900. In this way, the user can add and/or remove the magnet 3820, 3920 if magnetic attraction is desired or on longer desired. Further, the user can add additional magnets or remove magnets if a lesser strength of magnetic attraction is desired. For example, if a surface to which the capacitor 3800, 3900 is mounted is highly magnetic, the strength of magnetic attraction provided by the configuration of the magnets may be excessive. As such, the user can remove one or more of the magnets from the capacitor 3800, 3900 until the desired strength of magnetic attraction is achieved. On the other hand, if a surface to which the capacitor 3800, 3900 is mounted is relatively non-magnetic, the strength of magnetic attraction provided by the configuration of the magnets may be too low. As such, the user can add one or more additional magnets to the capacitor 3800, 3900 until the desired strength of magnetic attraction is achieved.

In some implementations, a bottom end of the capacitor 3800 (e.g., an area proximate to and including the bottom wall of the case 3802) may be removable from the rest of the case 3802 of the capacitor 3800. In some implementations, the bottom end of the capacitor 3800 may be attached by threading such that the bottom end of the capacitor 3800 may be removed by twisting the bottom end of the capacitor 3800 away from the rest of the case 3802. Removing the bottom end of the capacitor 3800 may reveal a compartment within which the magnet 3820 (and, e.g., additional magnets) can be placed and/or removed. In some implementations, the side wall of the case 3902 of the capacitor 3900 may include a slidable and/or otherwise openable door that reveals a compartment of the capacitor 3900 within which the magnet 3920 (and, e.g., additional magnets) can be placed and/or removed.

In some implementations, the case 3802, 3902 of the capacitor 3800, 3900 may be made from a magnetic material (e.g., a metallic material). The magnet 3820, 3920 may be held in place at least in part by magnetic attraction between the magnet 3820, 3920 and the case 3802, 3902. For example, the magnet 3802 may be magnetically attracted to the bottom wall of the case 3802 of the capacitor 3800, and the magnet 3920 may be magnetically attracted to the side wall of the case 3902 of the capacitor 3900. In some implementations, the case 3802, 3902 may be made from a non-magnetic material such as a plastic material. In such implementations, one or more other mechanisms or techniques may be used to fix the magnet 3820, 3920 in place, as described below.

In some implementations, the magnet 3820, 3920 may be affixed to a surface of the capacitor 3800, 3900 by one or more mounting mechanisms. For example, one or more brackets may be used to affix the magnet 3820 to the bottom wall of the case 3802. In some implementations, a bracket may be positioned around a surface of the magnet 3820, and one or more fasteners may be used to affix the bracket against the bottom wall of the case 3802. Similarly, one or more brackets may be used to affix the magnet 3920 to the side wall of the case 3902. In some implementations, a bracket may be positioned around a surface of the magnet 3920, and one or more fasteners may be used to affix the bracket against the side wall of the case 3902. In some implementations, an adhesive may be used to affix the magnet 3820, 3920 to the bottom wall of the case 3802 and/or the insulator cup 3808 and the side wall of the case 3902. In some implementations, the magnet 3820, 3920 may be held sufficiently in place by being wedged between the bottom wall of the case 3802 and the insulator cup 3808, or by being wedged between the side wall of the case 3902 and other components of the capacitor 3900. In some implementations, magnetic attraction between the magnet 3820, 3920 and other components of the capacitor 3800, 3900 (e.g., the case 3802, 3902) may assist in holding the magnet 3820, 3920 in place.

In some implementations, the magnet 3820, 3920 may be held in place at least in part by an epoxy. For example, once the magnet 3820, 3920 is positioned at its desired position within the case 3802, 3902 of the capacitor 3800, 3900, an epoxy can be introduced in proximity to the magnet 3820, 3920. Upon curing, the epoxy can provide sufficient strength for holding the magnet 3820, 3920 in its desired mounting location.

In some implementations, a cutout (e.g., a recess) may be provided in which the magnet 3820, 3920 can be seated (e.g., to assist in holding the magnet 3820, 3920 in place at its desired mounting location). The cutout may be provided in the case 3802, 3902 of the capacitor 3800, 3900 and/or in the insulator cup 3808 of the capacitor 3800. The cutout may provide a ridge that surrounds a perimeter of the magnet 3820, 3920 to keep the magnet 3820, 3920 in place. In this way, the magnet 3820, 3920 is prevented from sliding to other locations within the case 3802, 3902 of the capacitor 3800, 3900.

While the magnets 3820, 3920 have been illustrated as being positioned within the case 3802, 3902 of the capacitor 3800, 3900, in some implementations, the magnet 3820, 3920 may be mounted to an exterior of the case 3802, 3902. For example, in some implementations, the magnet 3820 may be mounted to a bottom surface of the bottom wall of the case 3802 of the capacitor 3800. The magnet 3820 may have a shape that substantially matches the shape of the bottom surface of the bottom wall. In this way, when the capacitor 3800 is mounted to a magnetic object (e.g., an air conditioning system), the capacitor 3800 can be positioned flush with the surface of the object. Similarly, in some implementations, the magnet 3920 may be mounted to an outside surface of the side wall of the case 3902 of the capacitor 3900. In some examples, the magnet 3920 may be wrapped around or substantially around the outside surface of the side wall of the case 3902 such that substantially all outside surfaces of the case 3902 are magnetic. The magnet 3820, 3920 may be mounted using one or more mounting mechanisms (e.g., brackets), an adhesive, an epoxy, one or more fasteners, etc. For example, one or more brackets may be used to mount the magnet 3820, 3920 in an interior of the case 3802, 3902 or at an exterior of the case 3802, 3902. In some implementations, the magnet 3820, 3920 may be a magnetic film that is applied to a portion of the case 3802, 3902 of the capacitor 3800, 3900. For example, the magnet 3820, 3920 may be a magnetic film applied to the exterior of the case 3802, 3902.

In some implementations, the magnet 3820, 3920 may have a thickness of approximately 4 mm. For example, in implementations in which the magnet 3820 is mounted to the bottom surface of the bottom wall of the case 3802 of the capacitor 3800, a width of approximately 4 mm for the magnet 3820 may provide sufficient strength of magnetic attraction without making the capacitor 3800 unwieldy (e.g., by adding excessive height to the capacitor 3800). Therefore, the capacitor 3800 does not take up excessive volume at its mounting location (e.g., at or within an air conditioning system).

In some implementations, one or more portions of the case 3802, 3902 of the capacitor 3800, 3900 are themselves magnetic, and/or the insulator cup 3808, 3908 is magnetic. For example, the capacitor 3800, 3900 may be designed such that the case 3802, 3902 is made from a magnetic material. In this way, the capacitor 3800, 3900 can be mounted in a variety of configurations as required for the particular application. For example, the bottom wall of the case 3802 of the capacitor 3800 and/or the insulator cup 3808, 3908 of the capacitor 3800, 3900 may be made from a magnetic material such that the bottom wall of the capacitor 3800 can be magnetically attracted to a magnetic object, and/or the side wall of the case 3902 of the capacitor 3900 may be made from a magnetic material such that the side wall of the capacitor 3900 may be magnetically attracted to a magnetic object.

While the magnets 3820, 3920 have been illustrated and described as belonging to different capacitors 3800, 3900, in some implementations, the magnet 3820 of FIG. 38 and/or the magnet 3920 of FIG. 39 may be incorporated into other capacitors described herein. For example, in some implementations, the magnet 3920 may also be incorporated into the capacitor 3800 (e.g., instead of or in addition to the magnet 3820), and vice versa. In some implementations, one or both of the magnet 3820 and the magnet 3920 may be incorporated into the other capacitors described herein, such as the capacitor 10 and/or the capacitor 200 and/or the capacitor 300 and/or the capacitor 400.

While many implementations have been described above (e.g., such as the implementations described with respect to FIGS. 38 and 39), other implementations are also possible. In some implementations, the capacitors described herein (e.g., the capacitor 10, 200, 300, 400, 3800, and/or 3900) may include multiple stacked magnets toward the bottom of the capacitor (e.g., similar to the capacitor 3800 of FIG. 38, and as described above, on the bottom wall of the case 3802 and/or between the bottom wall of the case 3802 and the insulator cup 3808). For example, two magnets having a circular shape (e.g. disk shape) may be stacked on top of each other such that the centers of the two magnets are in alignment. In some implementations, the two magnets may be made from one or more ceramic compounds (e.g., ferrite), for example, which can be produced by combining iron oxide and one or more metallic elements.

In some implementations (e.g., in addition to implementations that include the two stacked magnets described above), multiple magnets may be provided at the side wall of the capacitor (e.g., the side wall of the capacitor 3800, 3900). For example, two magnets may be provided inside the side wall of the capacitor 3800, 3900. The two magnets may have a curved shape (e.g., as described above). In some implementations, each of the curved magnets may be configured to interface with an inner wall of the case 3802, 3902 (e.g., at a location at or near, or including all or part of, the curved portion of the elliptical-shaped case 3802, 3902). In some implementations, the curved magnets may have dimensions of approximately 1 inch×1 inch and a thickness of approximately 1/10 of an inch. In some implementations, the two curved magnets are stacked vertically. For example, a first curved magnet may be provided at a first height between the side wall of the capacitor 3800, 3900 and the capacitive element 3804, 3904, and a second curved magnet may be provided at a second height (e.g., above or below the first height) between the side wall of the capacitor 3800, 3900 and the capacitive element 3804, 3904. In some implementations, each of the curved magnets may run around a full perimeter of the side wall of the capacitor 3800, 3900 (e.g., such that the magnets have a ring- or sleeve-type elliptical/oval shape). In some implementations, one of the magnets may run around a full perimeter while the other magnet runs around less than an entirety (e.g., a portion) of the perimeter. In yet additional implementations, both of the magnets may run around less than an entire perimeter (e.g., a portion of the circumference of the side wall). In some implementations, the two curved magnets are positioned at the same vertical height along the length of the side wall. In such implementations, the two curved magnets may each run less than the entire perimeter of the side wall. In some implementations, one or both of the two curved magnets may be a rare-earth magnet that includes neodymium.

In some implementations, one or both of the magnets placed inside the side wall may be positioned between an inside surface of the side wall and a portion of the insulator cup 3808, 3908. For example, one or both of the curved magnets may be positioned between the side wall and an up-turned skirt portion of the insulator cup 3808, 3908. In some implementations, the up-turned skirt may run further up the side wall an additional length than what is illustrated in the figures (e.g., in FIGS. 38 and 39). The multiple curved magnets may be stacked vertically or located at the same vertical height in a manner similar to that described above.

In some implementations, a liner may be positioned between the two curved magnets and the capacitive element 3804, 3904. For example, in implementations in which the curved magnets are not positioned between the side wall and the up-turned skirt of the insulator cup 3808, 3908, a liner may be applied over one or both of the curved magnets to separate the curved magnets from other components of the capacitor 3800, 3900. The liner may include a non-conductive material or any other material suitable for separating the magnets from other components of the capacitor 3800, 3900 (e.g., for minimizing effects of the magnet on the performance of the capacitive element 3804, 3904 and/or other components). In some implementations, the liner is a plastic adhesive material that can be applied over a surface of one or both of the curved magnets to separate the curved magnets from other components of the capacitor 3800, 3900. In some implementations, the liner can assist in holding the one or both of the curved magnets in place at the side wall of the capacitor 3800, 3900.

In some implementations, one or both of the two curved magnets may be positioned between the insulator cup 3808, 3908 of the capacitor 3800, 3900 and a bottom wall of the capacitor 3800, 3900. For example, one or both of the curved magnets may be placed in a position between the insulator cup 3808, 3908 and the bottom wall of the capacitor 3800, 3900. The curved magnets may be placed instead of or in addition to the magnet 3820 of FIG. 38. The one or both of the curved magnets may be positioned in one or more of the configurations described in the preceding paragraphs. For example, the two curved magnets may be stacked vertically (e.g., one on top of the other, with the two curved magnets optionally making contact with one another) or the two curved magnets may be positioned at the same vertical height of the capacitor 3800, 3900 (e.g., such that each of the curved magnets runs along less than an entire perimeter of the side wall, or such that each of the curved magnets runs along half of the perimeter of the side wall such that the sides of the two magnets make contact with each other). As mentioned above, one or more of the curved magnets may be a rare-earth magnet that include neodymium, while the disk shaped magnets may be made from one or more ceramic compounds (e.g., ferrite), although other materials are also possible. In some implementations, the neodymium curved magnets may have a relative higher (e.g., a substantially higher) degree of magnetic attraction as compared to that of the disk shaped ceramic magnets.

While the various disc shapes magnets and curved magnets have largely been described as being placed inside of the case 3802, 3902 of the capacitor 3800, 3900, in some implementations, one or more of the magnets described herein may be placed outside of the case 3802, 3902. For example, one or more of the disk shaped magnets may be positioned on a bottom (e.g., outside) surface of the bottom wall of the case 3802, 3902. The magnets may be affixed to the outside of the case 3802, 3902 by the strength of magnetic attraction. In some implementations, one or more mounting mechanisms (e.g., brackets), an adhesive, an epoxy, one or more fasteners, etc. may be used to assist in mounting the magnets to the outside of the case 3802, 3902. For example, one or more brackets may be used to mount the one or more magnets to the exterior of the case 3802, 3902. In some implementations, a liner (e.g., such as the liner described above) may be used to assist in mounting the one or more magnets to the case 3802, 3902.

Similarly, one or more of the curved magnets may be positioned on an outside surface of the side wall, of the case 3802, 3902. The magnets may be affixed to the outside of the case 3802, 3902 by the strength of magnetic attraction. In some implementations, one or more mounting mechanisms (e.g., brackets), an adhesive, an epoxy, one or more fasteners, etc. may be used to assist in mounting the magnets to the outside of the case 3802, 3902. For example, one or more brackets may be used to mount the one or more magnets to the exterior of the case 3802, 3902. In some implementations, a liner (e.g., such as the liner described above) may be used to assist in mounting the one or more magnets to the case 3802, 3902.

While the curved magnets have been described as having a curved shape that substantially interfaces with the side wall of the case 3802, 3902, in some implementations, a first wall of one or more of the curved magnets may have a curved shape that interfaces with the side wall of the case 3802, 3902, and an opposite wall (e.g., a wall opposite of the curved wall of the one or more magnet) may have a substantially flat shape. The substantially flat shape may allow the case 3802, 3902 to interface with a flat surface of a separate object (e.g., an air conditioning system). For example, in some implementations, one or more of the curved magnets may be positioned on an exterior of the side wall of the case 3802, 3902 (e.g., as described above). The opposite surface of the curved magnet may have a flat shape that can substantially interface with a flat magnetically-attractive surface, such as a metal wall of an air conditioning unit or system. The flat shape of the opposite surface of the one or more magnets may allow the capacitor 3800, 3900 to create a sufficient magnetic bond with the air conditioning unit or system, such that the capacitor cannot become inadvertently dislodged or misaligned from its intended mounting position.

In some implementations, one or more of the curved magnets may be configured to interface with both an outside of the side wall of the capacitor 3800, 3900 and the bottom wall of the capacitor 3800, 3900. For example, one or more of the curved magnets may include at least five relevant surfaces: a first curved surface (e.g., inside surface) that is configured to interface with the outside surface of the side wall, a second flat surface (e.g., inside surface) that is configured to interface with the bottom wall, and three additional flat surfaces (e.g., outside surfaces) that are configured to interface with one or more mounting location (e.g., of one or more surfaces of an air conditioning unit or system). The inside surfaces can allow the magnet to make intimate contact with the case of the capacitor 3800, 3900, thereby allowing the one or more magnets to maintain contact with the capacitor 3800, 3900 using one or more of the techniques described above. The three outside surfaces may allow the one or more magnets to make intimate contact with a mounting location, such as a corner mounting location that allows a bottom outside surface of the magnet to interface with a bottom mounting location, a first side outside surface perpendicular to the bottom outside surface to interface with a side mounting location, and a second side outside surface perpendicular to the bottom outside surface and the first side surface to interface with another side mounting location, thereby allowing the capacitor 3800, 3900 to be mounted in a corner target area while being placed on a bottom surface of the target area.

In some implementations, the magnet may include two outside surfaces (e.g., without a bottom outside surface) that allows the capacitor 3800, 3900 to be mounted in a corner target area without the capacitor 3800, 3900 necessarily being placed on (e.g., magnetically attracted to) a bottom surface of the mounting area. In this way, the capacitor 3800, 3900 can be mounted to a corner target area of an air conditioning unit or system while being suspended (e.g., without being placed on a bottom surface of the mounting area).

As described above, in some implementations, one or more of the curved magnets may be a rare-earth magnet that include neodymium, while the disk shaped magnets may be made from one or more ceramic compounds (e.g., ferrite), although it should be understood that other materials can additional or alternatively be used for any of the magnets described herein. In some implementations, the neodymium curved magnets may have a relative higher (e.g., a substantially higher) degree of magnetic attraction as compared to that of the disk shaped ceramic magnets. Such a configuration may, for example, provide additional magnetic mounting strength for implementations in which the capacitor 3800, 3900 is side mounted (e.g., mounted to a side surface of a target mounting location without the bottom wall of the case 3802, 3902 making contact with a bottom surface of the mounting location), sometimes referred to herein as a suspended mounting configuration. The relatively higher degree of magnetic attraction provided by one or more of the curved magnets may allow the capacitor 3800, 3900 to be mounted in such configurations without becoming dislodged or misplaced from the target location. For example, the relatively higher degree of magnetic attraction may prevent the capacitor 3800, 3900 from sliding down a wall of the mounting location due to the effects of gravity. In contrast, in implementations in which the bottom wall of the capacitor 3800, 3900 is mounted to a bottom surface of the target mounting location (e.g., on a bottom surface of an air conditioning unit or system), such additional strength of magnetic attraction may not be necessary to maintain the capacitor 3800, 3900 in proper mounting configuration. Nonetheless, additional curved magnets may also be included to provide additional and/or redundant magnetic attraction for mounting purposes.

In some implementations, any of the various magnets described herein (e.g., the magnet 3820 of FIG. 38, and/or the magnet 3920 of FIG. 39, and/or multiple ones of the magnets as described herein in any combination of configurations) may be mounted inside and/or outside of the case 3802, 3902 of the capacitor 3800, 3900. For example, to name a few examples, and not by way of limitation, multiple disk shaped magnets may be mounted on an exterior of the case 3802, 3902. In particular, multiple disk shaped magnets in a stacked configuration, as described above, may be positioned on an exterior (e.g., bottom) surface of the bottom wall of the capacitor 3800, 3900. In some implementations, a first disk shaped magnet may be mounted inside of the case 3802, 3902 and a second disk shaped magnet may be mounted outside of the case 3802, 3902 (e.g., on the exterior surface of the bottom wall of the capacitor 3800, 3900). In some implementations, any combination of one or more disk shaped magnets, and/or one or more strip shaped magnets, and/or one or more curved magnets, etc. may be mounted in any combination of inside and/or outside of the case 3802, 3902 of the capacitor 3800, 3900. In sum, while particular implementations are described herein and illustrated in the figures, it should be understood that any combination of the interior and/or exterior magnets described herein may be incorporated into the various capacitors 10, 200, 300, 400, 3800, and/or 3900 described herein.

In some implementations, providing magnetic mounting capability for the capacitor can provide a number of advantages. For example, in some implementations, a component to which or within which the capacitor is to be mounted (e.g., an air conditioning system) may or may not include an area (e.g., a designated area) that is typically used for mounting the capacitor. However, the user may desire to mount the capacitor elsewhere. By providing magnetic mounting capability, the number of options for mounting can be greatly increased.

In some implementations, the capacitor is mounted at locations that include metallic and/or magnetic objects. Such objects may impact the performance of the capacitor. In some implementations, the user may desire to mount the capacitor at a particular location such that particular operating conditions are achieved. Magnetic mountability of the capacitor can allow the user to mount the capacitor at such locations. In some examples, the capacitor can be mounted at locations that allow for shorter conductive connections (e.g., wires) between the capacitor's section cover terminals and common cover terminal and the device to which the capacitor is connected. Without such flexibility in possible mounting locations, the wires may be excessively long and may be susceptible to being cut or broken along with being susceptible to noise and/or distortions.

The capacitor and the features thereof described above are believed to admirably achieve the objects of the invention and to provide a practical and valuable advance in the art by facilitating efficient replacement of failed capacitors. Those skilled in the art will appreciate that the foregoing description is illustrative and that various modifications may be made without departing from the spirit and scope of the invention, which is defined in the following claims. 

1. An apparatus comprising: a case having an elliptical cross-section capable of receiving a plurality of capacitive elements, one or more of the capacitive elements providing at least one capacitor having a first capacitor terminal and a second capacitor terminal; a cover assembly comprising: a deformable cover mountable to the case, a common cover terminal having a contact extending from the cover, at least three capacitor cover terminals, each of the at least three capacitor cover terminals having at least one contact extending from the deformable cover, wherein the deformable cover is configured to displace at least one of the at least three capacitor cover terminals upon an operative failure of at least one of the plurality of the capacitive elements, and at least four insulation structures, wherein one of the four insulation structures is associated with one of the at least three capacitor cover terminals; and a first conductor capable of electrically connecting the first capacitor terminal of a capacitor provided by one of the plurality of capacitive elements to one of the at least three capacitor cover terminals and a second conductor capable of electrically connecting the second capacitor terminal of the capacitor provided by one of the plurality of capacitive elements to the common cover terminal.
 2. The apparatus of claim 1, wherein the plurality of capacitive elements are each separately wound.
 3. The apparatus of claim 1, wherein the combined capacitance value of one of the plurality of capacitance elements is greater than about 4.0 microfarads.
 4. The apparatus of claim 1, wherein each of the at least four insulation structures is cup shaped.
 5. The apparatus of claim 1, wherein each of the insulation structures is colored.
 6. The apparatus of claim 1, wherein at least two of the insulation structures are differently colored.
 7. The apparatus of claim 1, wherein the at least one capacitor has a capacitance value in a range of about 1.5 microfarad to about 5.0 microfarad.
 8. An apparatus comprising: an case having an elliptical cross-section capable of receiving a plurality of capacitive elements, one or more of the capacitive elements providing at least one capacitor having a first capacitor terminal and a second capacitor terminal; a cover assembly comprising: a deformable cover mountable to the case, a common cover terminal having a contact extending from the cover, at least three capacitor cover terminals, each of the at least three capacitor cover terminals having at least one contact extending from the deformable cover, wherein the deformable cover is configured to displace at least one of the at least three capacitor cover terminals upon an operative failure, and at least four colored insulation structures, wherein one of the four colored insulation structures is associated with one of the at least three capacitor cover terminals; and a first conductor capable of electrically connecting the first capacitor terminal of a capacitor provided by one of the plurality of capacitive elements to one of the at least three capacitor cover terminals and a second conductor capable of electrically connecting the second capacitor terminal of the capacitor provided by one of the plurality of capacitive elements to the common cover terminal.
 9. The apparatus of claim 8, wherein the plurality of capacitive elements are each separately wound.
 10. The apparatus of claim 8, wherein the combined capacitance value of one of the plurality of capacitance elements is greater than about 4.0 microfarads.
 11. The apparatus of claim 8, wherein each of the at least four colored insulation structures is cup shaped.
 12. The apparatus of claim 8, wherein at least two of the colored insulation structures are differently colored.
 13. The apparatus of claim 8, wherein the at least one capacitor has a capacitance value in a range of about 1.5 microfarad to about 5.0 microfarad.
 14. An apparatus comprising: a case having an elliptical cross-section capable of receiving a plurality of capacitive elements, one or more of the capacitive elements providing at least one capacitor having a first capacitor terminal and a second capacitor terminal, the at least one capacitor having a capacitance value in a range of about 1.5 microfarads to about 5.0 microfarads; a cover assembly comprising: a deformable cover mountable to the case, a common cover terminal having a contact extending from the cover, at least three capacitor cover terminals, each of the at least three capacitor cover terminals having at least one contact extending from the deformable cover, wherein the deformable cover is configured to displace at least one of the at least three capacitor cover terminals upon an operative failure, and at least four insulation structures, wherein one of the four insulation structures is associated with one of the at least three capacitor cover terminals; and a first conductor capable of electrically connecting the first capacitor terminal of a capacitor provided by one of the plurality of capacitive elements to one of the at least three capacitor cover terminals and a second conductor capable of electrically connecting the second capacitor terminal of the capacitor provided by one of the plurality of capacitive elements to the common cover terminal.
 15. The apparatus of claim 14, wherein the plurality of capacitive elements are each separately wound.
 16. The apparatus of claim 14, wherein the combined capacitance value of one of the plurality of capacitance elements is greater than about 4.0 microfarads.
 17. The apparatus of claim 14, wherein each of the at least four insulation structures is cup shaped.
 18. The apparatus of claim 14, wherein each of the at least four insulation structures is colored.
 19. The apparatus of claim 14, wherein at least two of the at least four insulation structures are differently colored. 